delegate pack - the river restoration centre
TRANSCRIPT
River Restoration Centre 12th Annual Network Conference
Managing Rivers at the
Local and Catchment Scale
Thursday 14th April 2011 Site visit to Croxall Lakes, Tuckers Holt Farm & Sence Valley Forest Park, Friday 15th April 2011
Jubilee Campus, University of Nottingham
England
Delegate Pack Including programme, abstracts,
site visit information and notepaper
12th Annual Network Conference
Managing Rivers at the
Local and Catchment Scale
Kindly sponsored by:
2
3
CONTENTS
Delegate lists 5
Programme of events 11
Abstracts for Session 1 18
Abstracts for Session 2 22
Abstracts for Session 3 30
Abstracts for Session 4 40
(Session 5) 50
Abstracts for Session 6 51
Abstracts for Session 7 56
Poster abstracts 67
Site visit information 93
4
5
DELEGATE LISTS
NAME ORGANISATION SITE
VISIT
EMAIL ADDRESS
RRC STAFF
Ian Brown Membership Officer [email protected]
Nick Elbourne Information Officer [email protected]
Joanne Evason Accounts Technician [email protected]
Di Hammond Senior Project Advisor [email protected]
James Holloway Project Advisor x [email protected]
Martin Janes Managing Director x [email protected]
Jenny Mant Science & Technical
Manager
RRC BOARD MEMBERS Emails have been hidden for privacy. Please contact delegates via RRC
Dan Alsop Chartered Engineer -------------------------------------------------------------
Fiona Bowles Wessex Water x -------------------------------------------------------------
Mervyn Bramley Independent Engineer &
Environmentalist
-------------------------------------------------------------
Karen Fisher KR Fisher Consultancy Ltd -------------------------------------------------------------
Andrew Pepper ATPEC River Engineering
Consultancy
x -------------------------------------------------------------
Kevin Skinner Atkins x -------------------------------------------------------------
Claire Thirlwall Thirlwall Associates x -------------------------------------------------------------
Geraldene Wharton Queen Mary University x -------------------------------------------------------------
-------------------------------------------------------------
DELEGATES -------------------------------------------------------------
Caroline Anderton Jeremy Benn Associates -------------------------------------------------------------
Natalie
Angelopoulos
University of Hull -------------------------------------------------------------
Paul Atkinson Tyne Rivers Trust -------------------------------------------------------------
Valerie Bain HR Wallingford -------------------------------------------------------------
Lyndon Baker Jacobs x -------------------------------------------------------------
Judith Bankhead Rivers Agency x -------------------------------------------------------------
Duncan Revell Environment Agency -------------------------------------------------------------
Alexandra Bence -------------------------------------------------------------
Mike Blackmore Cain Bio Engineering -------------------------------------------------------------
Matthew Blumler QWAG -------------------------------------------------------------
Lucy Bolton Environment Agency -------------------------------------------------------------
Will Bond Alaska Environmental
Contracting Ltd
x -------------------------------------------------------------
Mikk Bradley Halcrow Group -------------------------------------------------------------
David Bradley Apem Ltd -------------------------------------------------------------
Janice Bradley Nottinghamshire Wildlife
Trust
-------------------------------------------------------------
6
NAME ORGANISATION SITE
VISIT
EMAIL ADDRESS
Richard Breakspear Entec -------------------------------------------------------------
Chris Bromley SEPA -------------------------------------------------------------
Matt Buck Environment Agency x -------------------------------------------------------------
Ruth Bull Natural England -------------------------------------------------------------
Ian Butterfield Natural England -------------------------------------------------------------
Simon Cain Cain Bio Engineering -------------------------------------------------------------
David Carden Black & Veatch x -------------------------------------------------------------
Katherine Causer Environment Agency -------------------------------------------------------------
Susan Chambers Environment Agency -------------------------------------------------------------
Ruth Clarricoates Wiltshire Wildlife Trust x -------------------------------------------------------------
Elizabeth Clements RAFTS -------------------------------------------------------------
Chris Cockel Queen Mary University x -------------------------------------------------------------
Richard Cooper Environment Agency -------------------------------------------------------------
Carl Cornish RSPB -------------------------------------------------------------
Sarah Cowie Weetwood Services Ltd -------------------------------------------------------------
Andrew Crawford Environment Agency x -------------------------------------------------------------
Judith Crompton Environment Agency x -------------------------------------------------------------
Jo Cullis Halcrow Group -------------------------------------------------------------
Jenny Davies SEPA x -------------------------------------------------------------
Bella Davies Wandle Trust x -------------------------------------------------------------
Denise Delaney Office of Public Works -------------------------------------------------------------
Evan Dollar MWH -------------------------------------------------------------
Keli Donnelly SEPA -------------------------------------------------------------
Richard Dooley Office of Public Works -------------------------------------------------------------
Peter Downs University of Plymouth -------------------------------------------------------------
Ian Drew Manchester Metropolitan
University
-------------------------------------------------------------
Alastair Driver Environment Agency -------------------------------------------------------------
Rob Dryden Environment Agency -------------------------------------------------------------
Louise Duffy Environment Agency -------------------------------------------------------------
Paul East Land & Water Services Ltd -------------------------------------------------------------
Peter Easton Cain Bio Engineering -------------------------------------------------------------
Richard Edwards Salix -------------------------------------------------------------
Judy England Environment Agency -------------------------------------------------------------
Neil Entwistle University of Salford -------------------------------------------------------------
Chris Farmer Environment Agency x -------------------------------------------------------------
Robin Field River Nene Regional Park -------------------------------------------------------------
David Fraser Apem Ltd -------------------------------------------------------------
Jackie Galley SEPA -------------------------------------------------------------
Paul Gaskell Wild Trout Trust -------------------------------------------------------------
Sally German Arup -------------------------------------------------------------
Helen Gibbs Queen Mary University -------------------------------------------------------------
Morgane Gillet SEPA x -------------------------------------------------------------
Jo Goodson Atkins -------------------------------------------------------------
Alastair Graham Apem Ltd -------------------------------------------------------------
7
NAME ORGANISATION SITE
VISIT
EMAIL ADDRESS
Gareth Greer Rivers Agency x -------------------------------------------------------------
Ian Griffin WWT Consulting -------------------------------------------------------------
Sarah Guest Environment Agency x -------------------------------------------------------------
Anna Harlow Environment Agency -------------------------------------------------------------
Naomi Harris Nicholas Pearson
Associates
-------------------------------------------------------------
Gemma Harvey Queen Mary University -------------------------------------------------------------
Sylvia Haslam University of Cambridge -------------------------------------------------------------
Nathan Hawkings Willow Bank Natural
Engineering Solutions
-------------------------------------------------------------
Tom Hayek Yorkshire Wildlife Trust -------------------------------------------------------------
Francis Hayes SEPA -------------------------------------------------------------
James Hector Willow Bank Natural
Engineering Solutions
-------------------------------------------------------------
Alex Henshaw University of Nottingham -------------------------------------------------------------
George Heritage JBA Consulting -------------------------------------------------------------
David Hetherington Arup -------------------------------------------------------------
Jenni Hignett Nottinghamshire Wildlife
Trust
-------------------------------------------------------------
Chris Hill Leicestershire and Rutland
Wildlife Trust
x -------------------------------------------------------------
Jonathon Hillman Scott Wilson -------------------------------------------------------------
Melanie Hitchings Environment Agency -------------------------------------------------------------
Sadie Hobson Natural England -------------------------------------------------------------
David Holland Salix -------------------------------------------------------------
Julie Holmes SEPA -------------------------------------------------------------
Jayne Hornsby Land & Water Services Ltd x -------------------------------------------------------------
Lisa Hughes University of Nottingham -------------------------------------------------------------
Samantha Hughes -------------------------------------------------------------
Alex Humphreys Atkins -------------------------------------------------------------
Carys Hutton Yorkshire Wildlife Trust -------------------------------------------------------------
Tim Jacklin Wild Trout Trust -------------------------------------------------------------
Andy Jackson Leicestershire County
Council
x -------------------------------------------------------------
Daniel Johnson Environment Agency x -------------------------------------------------------------
Eilidh Johnston SEPA -------------------------------------------------------------
Halvard Kaasa Sweco Norge AS -------------------------------------------------------------
John Kane Department of Culture,
Arts & Leisure
x -------------------------------------------------------------
Chris Lally Isle of Man Water &
Sewage Authority
x -------------------------------------------------------------
Steve Lawrie Environment Agency x -------------------------------------------------------------
Hing Kin Lee Cascade Consulting -------------------------------------------------------------
Rachael Lem University of Nottingham -------------------------------------------------------------
Shaun Leonard Wild Trout Trust -------------------------------------------------------------
Tim Longstaff -------------------------------------------------------------
Oliver Lowe Environment Agency -------------------------------------------------------------
8
NAME ORGANISATION SITE
VISIT
EMAIL ADDRESS
Alasdair Maxwell Environment Agency x -------------------------------------------------------------
Paddy McCrudden Rivers Agency x -------------------------------------------------------------
Maureen McEwan SEPA x -------------------------------------------------------------
Julia MacPherson SEPA x -------------------------------------------------------------
Laura March -------------------------------------------------------------
Tim Meadows University of Nottingham -------------------------------------------------------------
Richard Melhuish Land & Water Services Ltd -------------------------------------------------------------
Helen Millier University of Westminster -------------------------------------------------------------
Margaret Miller SEPA x -------------------------------------------------------------
Jonathon Milliken Wessex Land and Water -------------------------------------------------------------
Carolyn Mills Apem Ltd -------------------------------------------------------------
Fergus Mitchell Natural England -------------------------------------------------------------
Neil Monoghan River Nene Regional Park -------------------------------------------------------------
Jane Moon Black & Veatch x -------------------------------------------------------------
Fiona Moore Land & Water Services Ltd -------------------------------------------------------------
Ian Morrissey Atkins -------------------------------------------------------------
RuthNeedham OnTrent and Central Rivers
Initiative
-------------------------------------------------------------
Geoff Nickolds Environment Agency -------------------------------------------------------------
Nicola Nineham -------------------------------------------------------------
Robert Oates Thames River Restoration
Trust
x -------------------------------------------------------------
Charlotte Owen Environment Agency -------------------------------------------------------------
Mark Owen Angling Trust x -------------------------------------------------------------
Chris Parker University of the West of
England
-------------------------------------------------------------
Emma Pearson Northumberland Wildlife
Trust
-------------------------------------------------------------
Tim Pickering Environment Agency -------------------------------------------------------------
Marc Piris Royal Haskoning -------------------------------------------------------------
Rob Pilcher RPS Group -------------------------------------------------------------
Mike Porter Environment Agency x -------------------------------------------------------------
Emma Quinlan University of Aberdeen x -------------------------------------------------------------
Victoria Raiment URS / Scott Wilson -------------------------------------------------------------
Tom Reid Environment Agency x -------------------------------------------------------------
Victor Richardson Thames 21 -------------------------------------------------------------
Robert Riddington Peter Brett Associates -------------------------------------------------------------
Mark Roberts OnTrent and Central Rivers
Initiative
-------------------------------------------------------------
John Robinthwaite JPR Environmental -------------------------------------------------------------
Michael Rogers Durham Wildlife Trust -------------------------------------------------------------
Alex Rothwell Environment Agency -------------------------------------------------------------
Lesley Saint Environment Agency -------------------------------------------------------------
Dave Sanderson Environment Agency -------------------------------------------------------------
Toni Scarr Environment Agency -------------------------------------------------------------
Emma Seddon Loughborough University -------------------------------------------------------------
9
NAME ORGANISATION SITE
VISIT
EMAIL ADDRESS
Andrea Shaftoe Environment Agency -------------------------------------------------------------
Janet Shaw Atkins x -------------------------------------------------------------
Lucy Shuker Queen Mary University -------------------------------------------------------------
Jonathon Simm HR Wallingford -------------------------------------------------------------
Ann Skinner Environment Agency x -------------------------------------------------------------
Michelle Smith University of Hull -------------------------------------------------------------
Emma Smith Halcrow Group -------------------------------------------------------------
Ben Smith Kings College x -------------------------------------------------------------
Brian Smith Environment Agency x -------------------------------------------------------------
Allan Snape Northumbrian Water Ltd -------------------------------------------------------------
Chris Spencer Land & Water Services Ltd -------------------------------------------------------------
Russell Spencer Cain Bio Engineering -------------------------------------------------------------
Kathy Stearne Natural England -------------------------------------------------------------
Mark Stollery Wessex Land and Water -------------------------------------------------------------
Niko Taktikos Cranfield University -------------------------------------------------------------
Caroline Tero Environment Agency -------------------------------------------------------------
Colin Thorne University of Nottingham x -------------------------------------------------------------
Mary Toland Northern Ireland
Environment Agency
x -------------------------------------------------------------
Holly Tucker Environment Agency -------------------------------------------------------------
Amanda Turner Heritage Lottery Fund -------------------------------------------------------------
Melissa Turner Apem Ltd -------------------------------------------------------------
Alison Tytherleigh Natural England -------------------------------------------------------------
Ralph Underhill RSPB x -------------------------------------------------------------
Rogier Vogeli -------------------------------------------------------------
Andy Went OHES Environmental -------------------------------------------------------------
Jenny Wheeldon Natural England -------------------------------------------------------------
Karen White Royal Haskoning -------------------------------------------------------------
Simon Whitton Environment Agency Wales -------------------------------------------------------------
Clare Williams Halcrow Group -------------------------------------------------------------
Sarah Williams Dorset Wildlife Trust -------------------------------------------------------------
Joanne Wilson RPS -------------------------------------------------------------
Lewis Winks Field Studies Council -------------------------------------------------------------
Jason Winslow Alaska Environmental
Contracting Ltd
-------------------------------------------------------------
Nikki Wood Environmental Gain Ltd -------------------------------------------------------------
Peter Worrall Penny Anderson Associates -------------------------------------------------------------
Julie Wozniczka OnTrent and Central Rivers
Initiative
-------------------------------------------------------------
Kayleigh Wyatt University of Nottingham -------------------------------------------------------------
Wendy Yorke Thames River Restoration
Trust
x -------------------------------------------------------------
Kyle Young Environment Agency -------------------------------------------------------------
10
PROGRAMME OF EVENTS
9:00 REGISTRATION & REFRESHMENTS
10:30 Session 1
CHAIR: Geraldene Wharton (Queen Mary, University of London & RRC Board)
Lecture Theatre 3 (LT3) - Floor D
Announcements: Martin Janes (River Restoration Centre) 5 min
10:35 Introduction: Geraldene Wharton (RRC Chair of Directors) 15 min
10:50 Keynote address: Emerging trends in river management and restoration:
An agenda for the early Twenty-first century.
Peter Downs (University of Plymouth)
20 min
11:10 Discussion 10 min
11:20 Engaging, Supporting and Transferring Knowledge for River
Restoration in Europe – the EU LIFE+ RESTORE Project.
Martin Janes (River Restoration Centre)
15 min
11:35 Discussion 5 min
11:40 SHORT BREAK TO MOVE TO SPLIT SESSIONS 20 min
11
12:00 Session 2:
FILLING GAPS IN KNOWLEDGE & INFORMATION RESOURCES
A – LINKING HYDROLOGY,
MORPHOLOGY AND ECOLOGY
B – NEW TOOLS FOR
RESTORATION
CHAIR: Peter Downs (University of Plymouth)
CHAIR: Mervyn Bramley (Independent
Engineer & Environmentalist & RRC Board)
Lecture Theatre 3 (LT3) –
Floor D
Lecture Theatre 2 (LT2) –
Floor C
Using simple 2d modelling and
geomorphology - habitat
associations to assist in floodplain
restoration. Caroline Anderton (JBA
Consulting) et al.
The fluvial information system:
Taking river restoration into the
future. Alastair Graham and Stuart
Clough (Apem Ltd)
15 min
12:15 Unravelling the complexities of
fish habitat interactions for
successful river rehabilitation.
Michelle Smith (University of Hull) et
al.
Quantifying catchment-scale
coarse sediment dynamics:
Implications for sustainable river
restoration projects.
Chris Parker (University of the West of
England) et al.
15 min
12:30 Discussion Discussion 15 min
12:45 LUNCH (plus 5 minutes to move to sessions)
Foyer (Floor A) and Coffee in C33 (Floor C),
with POSTER PRESENTATIONS
65 min
12
13:50 Session 3:
ENSURING SUCCESS
A – REVIEWING ACHIEVEMENTS B – CATCHMENT-SCALE
PLANNING &
IMPLEMENTATION
CHAIR: Kevin Skinner (Atkins & RRC Board)
CHAIR: David Fraser (APEM)
Lecture Theatre 3 (LT3) – Floor D Lecture Theatre 2 (LT2) – Floor C
Assessing the impact of river
rehabilitation schemes – A missing
dimension or unnecessary
procedure? Natalie Angelopoulos
and Ian Cowx (University of Hull).
The River Nar SSSI Restoration
Strategy & Plan.
James Holloway and Karen Fisher (The River Restoration Centre)
15 min
14:05 Rehabilitation of hydro-
geomorphological processes in a
lowland UK river: Quantifying
and assessing the effects of large
wood reintroductions.
Gemma Harvey (Queen Mary,
University of London) et al.
An approach to improving the
empirical evidence base for
biological responses to
geomorphological pressures. Chris
Bromley (SEPA) et al.
15 min
14:20 Post-project appraisal of the
morphological and ecological
performance of the Harbertonford
flood alleviation scheme on the
River Harbourne, Devon. Kayleigh
Wyatt and Colin Thorne (University
of Nottingham)
Catchment Sensitive Farming - A
voluntary approach to
implementing River Basin
Management Plan measures in
sensitive river catchments. Alison
Tytherleigh (Natural England) et al.
15 min
14:35 Discussion Discussion 15 min
14:50 BREAK (plus 5 minutes to move to sessions)
Coffee in Foyer and C33 (Floor C, with POSTER PRESENTATIONS) 35 min
13
15:25
Session 4:
THE LONG & SHORT OF IT –
LONGITUDINAL & LATERAL CONNECTIVITY
A – SEDIMENT DYNAMICS &
FLOODPLAINS
B – CONTEMPORARY
APPROACHES TO IN-STREAM
BARRIERS
CHAIR: Colin Thorne (Univ. Nottingham)
CHAIR: Andrew Pepper (ATPEC
River Engineering Consultancy & RRC Board)
Lecture Theatre 3 (LT3) – Floor D Lecture Theatre 2 (LT2) – Floor C
Recreating an anastomosing
channel on the River Trent at
Croxall Lakes. George Heritage
(JBA Consulting) et al.
In stream barriers assessment –
A multidisciplinary approach.
Janet Shaw (Atkins) et al.
15 min
15:40 A framework for hydrological
connectivity management and site
suitability for delivery of
simultaneous ecosystem services
on a floodplain. Niko Taktikos
(Cranfield University) et al.
Weir removal assessment and
evidence base. Jenny Mant and
Andrew Pepper (RRC and ATPEC)
15 min
15:55 Targeting excessive fine sediment
in rural river systems - The rural
sediment tracing project. Carolyn
Mills (APEM Ltd) et al.
A simple way to ease fish and eel
passage across a sluice apron.
Mike Porter (Environment Agency) et
al.
15 min
16:10 Discussion Discussion 15 min
16:25 5 minutes to move to joint
session
5 minutes to move to joint
session 5 min
16:30
SESSION 5: Restoring rivers: The challenges of implementing whole–river plans and
implications for the wider river network
Jenny Wheeldon (Natural England) et al.
15 min
16:45 Discussion 15 min
17:00 EVENING TEA
C33 (Floor C) – with POSTER PRESENTATIONS 60 min
14
18:00 Session 6:
PARTNERSHIP WORKING & LOCAL ENGAGEMENT
Announcements & Introduction 5 min
CHAIR: Claire Thirlwall (Thirlwall Associates)
Lecture Theatre 3 (LT3) – Floor D
18:05 Partnerships for river restoration - More for less?
Ruth Needham (OnTrent) et al. 15 min
18:20 How the Thames won the 2010 International Riverprize.
Alastair Driver (Environment Agency)
10 min
18:30 Development of a Water Framework Directive-driven restoration
strategy for the River Trent. David Fraser (Apem Ltd) et al.
15 min
18:45 Discussion 5 min
18:50 MOVE TO SPLIT SESSIONS 5 min
15
Session 7:
A – NOTT FAR FROM
NOTTINGHAM
B – PARTNERSHIPS
GREAT & SMALL
CHAIR: Karen Fisher (KR Fisher Consultancy & RRC Board)
CHAIR: Fiona Bowles (Wessex Water)
Lecture Theatre 3 (LT3) – Floor D Lecture Theatre 2 (LT2) – Floor C
18:55 “Trout in the Town” – Urban River
Restoration and Promotion by
Local Community Groups.
Paul Gaskell (Wild Trout Trust)
3 Rivers clean up – Ravensbourne
catchment SE London - A
partnership approach to invasive
species removal on a catchment
scale. Victor Richardson and
Matthew Blumler (Thames 21 and
QWAG)
15 min
19:10 Assessing the past for the future: A
case study of Nottinghamshire's
forgotten water meadows. Jon
Hillman (Scott Wilson) et al.
Partnership works in Northern
Ireland – Always start with a cup
of tea. Judith Bankhead and Gareth
Greer (Rivers Agency)
15 min
19:25 Restoration of riparian habitats on
the old course of the River Ise in
Northamptonshire. Robin Field
(Revital-ISE) et al.
The role of self-help groups in
river flood management. Jonathan
Simm (HR Wallingford)
15 min
19:40 Discussion Discussion 20 min
20:00 ------ END OF CONFERENCE ------
16
ABSTRACTS
PRESENTATION SESSIONS
& POSTERS (pg 67)
Kindly sponsored by:
17
SESSION 1
Emerging trends in river management and restoration:
An agenda for the early twenty-first century
P. W. DOWNS
Associate Professor – School of Geography, Earth and Environmental Sciences,
University of Plymouth
RESTORE – Rivers: Engaging, Supporting and Transferring knOwledge
for Restoration in Europe
M. D. JANES1 & N. D. ELBOURNE2 1Managing Director – The River Restoration Centre
2Information Officer – The River Restoration Centre
NOTES…
18
EMERGING TRENDS IN RIVER MANAGEMENT AND RESTORATION:
AN AGENDA FOR THE EARLY TWENTY-FIRST CENTURY
P. W. DOWNS
Associate Professor – School of Geography, Earth and Environmental Sciences, University of Plymouth
Abstract
River management in the 1990s saw the widespread adoption of practices fundamental to the
concept of „river restoration‟, thus initiating a new era in the relationship between humans and
their rivers. At its most elemental, river management now involves three intertwined
components: water resources management, management of risk associated with near-river
hazards, and conservation management practices. However, as these components have
existed for thousands, hundreds, and tens of years, respectively, management initiatives are
frequently centred on modifying practices for managing water resources and hazards to
accommodate society‟s legislated concerns for conservation. In practice therefore, river
restoration has usually to contend with severe pre-existing environmental degradation and
catchment development pressures that will result in further cumulative impacts on the
structure and function of natural ecosystems, if left unchecked.
From a viewpoint in early 2011, several themes look set to influence river management and
restoration over the coming decades. First, the adoption of an ecosystem services philosophy
may provide the elusive common element that allows river basin management to become truly
integrated. This, in concert with the completion of the first cycle of adaptive management
will lead to an increasing appreciation for „natural infrastructure‟ as the basis for
environmental resilience. In parallel, the governance of rivers may be achieved through a
„panarchy‟ of stakeholders adopting an increasingly active rather than passive approach to
river conservation. Examples include the acquisition of river corridor lands funded by
donations to non-government organizations, an escalating number of restoration businesses
that deliver river restoration commercially in exchange for mitigation payments, and the
increasing importance of river trusts as entities that can mediate between regulators,
businesses and landowners to efficiently facilitate the adoption of innovative procedures.
Third is an increasing appreciation that river management measures have a lifespan that
precludes an assumption of environmental stationarity: whereas standard environmental
impact assessments have been unable to control cumulative environmental degradation,
heightened concern for global climate change may achieve just that by placing a far greater
emphasis on predictive modelling of conservation concerns such as biological responses to
habitat change. Finally, we may put into practice the adage that “you can‟t manage what you
don‟t measure”. Calls for accountability in public finances will result in a move towards
evidence-based river management monitored over meaningful time periods, facilitated by
recent developments in remote sensing and passive monitoring which will make feasible the
extensive and intensive monitoring of environmental parameters.
Keywords: Water resources; Risk; Conservation management; Ecosystem
services; Adaptive management; River stakeholders; Environmental
impact; Evidence-based river management; Post-project appraisal
19
RESTORE – RIVERS: ENGAGING, SUPPORTING AND
TRANSFERRING KNOWLEDGE FOR RESTORATION IN EUROPE
M. D. JANES1 & N. D. ELBOURNE
2
1Managing Director – The River Restoration Centre, Cranfield Campus, Cranfield, Bedfordshire, MK43 0AL
[email protected] 2Information Officer – The River Restoration Centre
Abstract
RESTORE is an EU LIFE+ Information and Communication funded project that will develop
a network linking the main target audience (MTA) of policy makers, river basin planners and
a wide range of practitioners and experts across Europe. The work will share information and
best practice on river restoration activities to aid implementation for EU Water Framework
Directive (WFD) delivery. The project commenced in September 2010 and will finish in
2013.
RESTORE will help identify regionally common (N, E, S, W Europe) issues and constraints,
and help the MTA implement environmental directives by raising their awareness of how to
deliver effective river restoration. It has been identified that the main problem affecting river
restoration practitioners is not a lack of expertise, but a lack of opportunities for sharing best
practice and knowledge.
RESTORE addresses the need to both understand and promote best practice and it will
provide the platform for effective knowledge transfer, information sharing and discussion of
strengths and weaknesses of river restoration techniques and options. One way in which it
will do this is by holding sector-specific engagement events, field visits and a major
international conference. Another key output will be a moderated online wiki-database of
case-studies highlighting lessons learnt and best practice, and also key project contacts, which
will continue to operate beyond the life of the project.
The principal objectives of RESTORE are:
- Support river restoration practices across Europe
- Build up existing river restoration network capacity
- Promote effective river restoration knowledge transfer
- Establish long-term river restoration knowledge sharing
Keywords: River Restoration; Information; Communication; Policy makers; River
Basin Planners; Practitioners; Stakeholders; Main Target Audience
20
NOTES…
21
SESSION 2A:
LINKING HYDROLOGY,
MORPHOLOGY AND ECOLOGY
Using simple 2d modelling and geomorphology -
Habitat associations to assist in floodplain restoration
C. ANDERTON et al.
Senior Analyst – JBA Consulting
Unravelling the complexities of fish habitat interactions
for successful river rehabilitation
M.A.SMITH et al.
PhD student – Hull International Fisheries Institute, University of Hull
NOTES…
22
USING SIMPLE 2D MODELLING AND GEOMORPHOLOGY -
HABITAT ASSOCIATIONS TO ASSIST IN FLOODPLAIN RESTORATION
C. ANDERTON1, G. L. HERITAGE
2, L. HICKS
3, S. MCFARLAND
4 & S. COOKSLEY
5
1Senior Analyst – JBA Consulting, Port Neuk, Longcraig Road, South Queensferry, Edinburgh EH30 9TD
[email protected] 2Technical Director – JBA Consulting, The Brew House, Wilderspool Park, Warrington WA4 6HL
3Senior Analyst – JBA Consulting, Denison House, Hexthorpe Road, Doncaster, South Yorkshire DN4 0BF
4Principal Engineer – Aberdeenshire Council, Carlton House, Arduthie Road, Stonehaven AB39 2DP
5Project Officer – Dee Catchment Partnership, The Macaulay Institute, Aberdeen AB10 1YP
Abstract
The reinstatement of channel and floodplain process alongside that of form is recognised as
fundamental for sustainable river restoration. Opportunities often exist to restore functionality
across floodplains that have suffered from hydrological and sediment disconnection as a result
of flow regime changes and physical flood protection measures. However, engineered
approaches to habitat creation often dominate over assisted natural recovery options. This
paper demonstrates a simple methodology to identify natural floodplain features and to
predict the ecological gains generated by their restoration on the River Dee upstream of
Braemar, Royal Deeside.
Identification of palaeo-features present across the floodplain was initially achieved using
aerial imagery, facilitating targeted field survey of their geomorphology and ecology. Linked
data from the two surveys allowed empirical associations to be established. A 2D cellular
based inundation model (JFLOW) was used to model surface water flood extent and
frequency based on an aerial LiDAR digital terrain model and flows from the Mar Lodge
gauging station. This established the present flood regime and the potential regime following
selective defence removal. Associations between the present flood regime, morphological
features and vegetative assemblages were then established and these were transferred to the
modelled scenarios to predict altered floodplain community structure.
It is clear from the results for the River Dee simulations that floodplain geomorphological
diversity is high but process diversity is low due to poor hydrological connectivity. Process
diversity is seen to increase dramatically once flood connectivity is re-established. Palaeo-
features presently subject to a flood-poor relatively uniform over-dry hydrological regime
become subjected to spatially variable flood flows dependent on proximity and connectivity
to the active channel network. This diversity in form and process recreates floodplain physical
habitats lost to the system providing conditions for the spread of species previously highly
restricted in their distribution.
Keywords: Hydromorphology; LiDAR; Floodplain features
23
UNRAVELLING THE COMPLEXITIES OF FISH HABITAT
INTERACTIONS FOR SUCCESSFUL RIVER REHABILITATION
M.A.SMITH1, N.ANGELOPOULOS
2, T.COULTHARD
3 AND I.G.COWX
4
1PhD student – Hull International Fisheries Institute, University of Hull, East Yorkshire HU6 7RX
[email protected] 2Research Assistant – Hull International Fisheries Institute, University of Hull, East Yorkshire
3 Professor of Physical Geography – University of Hull, East Yorkshire 4 Professor of Applied Fisheries Science – University of Hull, East Yorkshire
Abstract
European rivers require considerable intervention to meet the Water Framework Directive
objectives of Good Ecological Status / Potential. To achieve this, attention is now focussing
on the ecological impacts of hydromorphological degradation of rivers. River
hydromorphology, driven by river flow and through a complex interaction between physical
characteristics including substrate, depth and channel width, creates a variety of physical
conditions. Although it is recognised that there is a relationship between physical habitat and
aquatic communities very few studies make the link between physical habitat conditions and
fish community structure. These interactions create diversity in physical habitat for all life
stages of fish, which are reflected by community structure.
If river rehabilitation is to be successful, the consequences of modifying (improving) in-
stream physical characteristics through active intervention on all life stages of fish needs to be
fully understood. This paper examines the importance of major physical habitat variables to
fish species through a series of case studies from a variety of rivers across the UK. Methods
of assessing physical habitat will be discussed paying particular attention to the practical
applications of these methods in terms of river restoration and providing useful outputs for
managers.
Keywords: Water Framework Directive; Hydromorphology; Habitat
24
NOTES…
25
SESSION 2B:
NEW TOOLS FOR RESTORATION
The fluvial information system: Taking river restoration into the future
A.J. GRAHAM1 & S. CLOUGH2 1Senior Remote Sensing Scientist – APEM
2Director – APEM Remote Sensing
Quantifying catchment-scale coarse sediment dynamics:
Implications for sustainable river restoration projects
CHRIS PARKER et al.
Senior Lecturer of Physical Geography – Department of Geography and Environmental Management,
University of the West of England
NOTES…
26
THE FLUVIAL INFORMATION SYSTEM:
TAKING RIVER RESTORATION INTO THE FUTURE
A.J. GRAHAM1 & S. CLOUGH
2
1Senior Remote Sensing Scientist – APEM Remote Sensing, APEM Manchester Lab, Riverview, A17
Embankment Business Park, Heaton Mersey, Stockport SK4 3GN [email protected] 2Director – APEM Remote Sensing, APEM Manchester Lab, Stockport
Abstract
River experts understand that our knowledge of ecology and geomorphology is limited by our
lack of methods applicable to catchment scale processes. The EU Water Framework Directive
states that surface waters must be managed at catchment scales and this has created a need for
a new approach to high-resolution catchment scale data collection in fluvial environments.
Remote Sensing has developed techniques that enable the mapping of parameters such as
water depth, grain size and habitat type with sub-metric resolutions over large areas. With
greatly increased levels of information now available to them, river and fisheries managers
can make better informed data-driven decisions about catchment scale ecology and
geomorphology. Extracting spatially explicit information from large image databases poses a
significant challenge which must be resolved if fluvial remote sensing methods are to deliver
their potential.
Here we detail the Fluvial Information System (FIS), a raster based GIS-type system designed
to manage fluvial remote sensing data and automatically extract meaningful information.
Using aerial imagery within such a system allows river restoration experts to identify critical
obstacles to effective naturalised flow: sediment traps, canalisation, flood plain connectivity
etc. The power of the FIS rests on its 2D river coordinate system modelled on a system that
follows the river path as calculated by curve fitting whilst the cross-stream direction is locally
orthogonal to the main axis and is know as the river coordinate system. Further enhancements
in the FIS are innovative visualisation methods for the depth and clast size data that is
computed.
This adaptation of GIS to fluvial systems is a significant innovation with consequences to
fundamental river science and management. Once the restoration requirements have been
identified, the FIS (in conjunction with timely aerial data capture) can be used to monitor the
effectiveness and progress of any remedial works that have been enacted. With the FIS,
managers can make use of the information contained in high resolution imagery to allow
stakeholders to quantify the available habitat for important species such as salmonids and in
the support of river management decisions. The value of the FIS will be demonstrated through
the use of key example projects undertaken by APEM.
Keywords: River depth; Remote sensing; Sediment mapping; GIS;
Spatial modelling
27
QUANTIFYING CATCHMENT-SCALE COARSE SEDIMENT DYNAMICS:
IMPLICATIONS FOR SUSTAINABLE RIVER RESTORATION PROJECTS
CHRIS PARKER1, COLIN R. THORNE
2 & NICHOLAS. J. CLIFFORD
3
1Senior Lecturer of Physical Geography – Department of Geography and Environmental Management,
University of the West of England, Bristol [email protected] 2Professor of Physical Geography – School of Geography, University of Nottingham
3Professor of Physical Geography – Department of Geography, King’s College London
Abstract
The transfer of coarse sediment within the fluvial system exerts an important influence over
physical habitat structures within rivers which, in turn, are a key control over river ecology. It
follows that sustainable and effective river restoration design depends on understanding
coarse sediment dynamics within the fluvial system. As a result, catchment-scale river
channel sediment dynamics must be taken into account within river restoration projects as
well as flood risk management projects. Yet, due to limitations on data describing British
rivers, no existing approach to representing coarse sediment dynamics is both scientifically
robust and utilizable at the catchment-scale.
A new reach-based sediment balance model has been developed, called ST:REAM (Sediment
Transport: Reach Equilibrium Assessment Method). ST:REAM is functional using no more
than slope, width and discharge data that are widely available in British rivers. The outputs
from ST:REAM are in the form of predicted CSRs (Capacity Supply Ratios) which compare
the mass of sediment predicted to enter a reach with the mass of sediment predicted to leave
that reach.
ST:REAM has many potential applications within British river management, these include:
providing an indication of reaches with poor hydromorphological status due to sediment
imbalance; identifying the impact of proposed restoration plans on catchment sediment
transfer; and identifying reaches of channel that pose significant flood risk due to excessive
deposition. However, because of the scale at which it represents sediment dynamics,
ST:REAM is of most value when providing a broad-scale picture of predicted reach sediment
status across a catchment.
Of additional relevance to river restoration practitioners is the method used to automatically
define reach boundaries within ST:REAM. It has the potential to identify river reach
boundaries that are relevant across various aspects of the fluvial system, and that therefore can
act as a relevant spatial framework for integrated catchment management.
Keywords: Geomorphology; Catchment management; Flood risk
28
NOTES…
29
SESSION 3A:
REVIEWING ACHIEVEMENTS
Assessing the impact of river rehabilitation schemes –
A missing dimension or unnecessary procedure?
N. ANGELOPOULOS et al.
Research Assistant – Hull International Fisheries Institute, University of Hull
Rehabilitation of hydrogeomorphological processes in a lowland UK river:
Quantifying and assessing the effects of large wood reintroductions
GEMMA L. HARVEY et al.
Lecturer in Physical Geography – Queen Mary, University of London
Post-project appraisal of the morphological and ecological performance of the
Harbertonford flood alleviation scheme on the River Harbourne, Devon
KAYLEIGH WYATT1 & COLIN THORNE2 1Student: MSc Environmental Management – University of Nottingham
2Professor and Chair of Physical Geography – Univ. of Nottingham
NOTES…
30
ASSESSING THE IMPACT OF RIVER REHABILITATION SCHEMES –
A MISSING DIMENSION OR UNNECESSARY PROCEDURE?
N. ANGELOPOULOS1, M. A SMITH
1 & I. G. COWX
2
1Research Assistants – Hull International Fisheries Institute, University of Hull, East Yorkshire HU6 7RX
[email protected] 2Professor of Applied Fisheries Science – University of Hull, East Yorkshire. HU6 7RX
Abstract
Developing environmentally acceptable methods for river rehabilitation is now a fundamental
requirement to meet objectives under the EU Water Framework Directive (WFD) and
Habitats Directive. Although literature on restoration ecology is extensive, it remains
fragmented and rarely is the success, or other findings of projects assessed to determine the
efficacy of the projects to meet these objectives. One of the reasons for this failure is lack of
clearly defined end-points against which to measure success. This lack of effort is a serious
impediment for managers who have to make decisions on the most cost-effective restoration
measures to address hydrogeomorphological degradation in different river types. The
objective of this contribution is to review the findings of a range of rehabilitation schemes on
different rivers across England to establish a procedure to assess the efficacy of rehabilitation
schemes and enable managers to choose the most cost effective measures for various
scenarios.
The paper will provide an integrated approach to project planning that deals with both the
variability of river rehabilitation and complexity of an ecosystem. Restoration projects should
not be selected at random and therefore, it is essential that any future rehabilitation scheme
must follow a framework that firstly prioritises projects and secondly identifies multiple
objectives. These objectives should work towards benefiting fish communities, taking in to
account the needs of individual fish species and size class, to recognise the „missing‟ habitat
and identify the habitat enhancement technique needed. Measuring project success can be
challenging but nevertheless it is imperative to include pre-assessment, short-term and long-
term monitoring in to the framework. The challenges for future monitoring will be addressed
with ideas to overcome the difficulties of comparing rehabilitation effectiveness across rivers.
Keywords: Water Framework Directive; Habitats Directive; Restoration;
Hydrogeomorphology; Monitoring
31
REHABILITATION OF HYDROGEOMORPHOLOGICAL PROCESSES IN A
LOWLAND UK RIVER: QUANTIFYING AND ASSESSING
THE EFFECTS OF LARGE WOOD REINTRODUCTIONS
GEMMA L. HARVEY1, ALEXANDER J. HENSHAW
2, CHRIS PARKER
3,
CARL SAYER4 & MURRAY THOMPSON
5
1Lecturer in Physical Geography – Queen Mary, University of London, London [email protected]
2Postdoctoral Research Fellow – University of Nottingham, Nottingham
3Senior Lecturer in Physical Geography – University of the West of England, Bristol
4Lecturer in Physical Geography – University College London, London
5PhD student – Natural History Museum, London
Abstract
Large pieces of wood, including entire fallen trees, are a natural feature of many river systems
and have been shown to be an important control on river morphology, sediment retention and
the construction of habitats. Wood can act as an „ecosystem engineer‟ in river channels by
modifying local geomorphic, hydraulic, and sedimentological processes, increasing habitat
diversity and potentially sustaining water quality. However, within Europe and particularly
the UK, wood has been perceived as a flood hazard and, consequently, lowland rivers have
been subject to routine clearance of large wood in order to improve flow conveyance.
Reintroductions of large wood increasingly features in river rehabilitation projects, but,
despite considerable research activity in this area, many practical attempts to input large wood
features into river channels have incorporated costly engineered structures, which have often
been ineffective in improving habitat heterogeneity and biodiversity. Further research is
required to improve understanding of the nature and extent of the impacts of large wood on
habitat complexity and connectivity in order to inform river rehabilitation practice.
A research programme has been initiated that aims to characterize and quantify changes in
hydromorphological processes and habitat complexity following wood reintroduction. This
will be achieved through detailed field study incorporating comparisons between adjacent
reaches and monitoring of changes over time. The field study is based upon selected reaches
of the upper River Bure, Norfolk, where a programme of large wood reintroduction is being
undertaken by the National Trust. It is anticipated that the research findings from this project
will contribute to the evidence base for wood-related flood risks in lowland UK rivers by
monitoring the mobility of wood assemblages, assessing stage-discharge relationships and
exploring the influence of wood assemblages on fine sediment storage and transfer in a low
energy system.
Keywords: River Bure; Wood; Large woody debris; Habitat; Sediment; Flood risk;
Hydraulics
32
POST-PROJECT APPRAISAL OF THE MORPHOLOGICAL AND
ECOLOGICAL PERFORMANCE OF THE HARBERTONFORD FLOOD
ALLEVIATION SCHEME ON THE RIVER HARBOURNE, DEVON
KAYLEIGH WYATT1 & COLIN THORNE
2
1Student: MSc Environmental Management – University of Nottingham, c/o Sir Clive Granger Building,
University Park, Nottingham, NG7 2RD [email protected] 2Professor and Chair of Physical Geography – Univ. of Nottingham, Room B26f, Sir Clive Granger Building
Abstract
The River Harbourne flood alleviation scheme (FAS) was implemented in 2002, with the
objectives of reducing flood risk in the village of Harbertonford and limiting the need for
channel maintenance, while simultaneously promoting the environmental and conservational
value of the watercourse. Commenting on the scheme, Sir John Harman, the then Chair of the
Environment Agency, described the project at Harbertonford as representing „the future of
flood defence schemes‟ in England and Wales.
In the context of this statement, this paper evaluates the morphological and ecological
performance of the FAS based on the results of a series of post-project appraisals (PPAs)
performed since its implementation. Channel morphology was assessed using stream
reconnaissance techniques and cross-sectional surveys, while stream and riparian ecology was
investigated using river habitat survey (RHS) data, diatom sampling, benthic macro-
invertebrate sampling and vegetation surveys.
Statistical analyses of the morphological and ecological data reveal that the Harbourne is a
highly dynamic watercourse that is still responding to implementation of the FAS. There is
evidence that rates of gravel accumulation in the Harbourne within Harbertonford have been
reduced by channel improvements undertaken as part of the FAS. In terms of ecological
value, positive changes were concentrated in wetlands created in the footprint of the flood
storage area upstream of the settlement, while negative changes were found in reaches located
downstream of Parker Dam and in the extensively modified channel in the downstream
reaches of the FAS.
In summary, although morphological and ecological responses to the FAS on the River
Harbourne are continuing, and while the project can be judged as a success to date, the
lessons so far learned through PPAs of this high profile scheme could and should be
considered in the design of similar schemes proposed for other watercourses throughout the
UK.
Keywords: Flood risk; Channel modification; Stream reconnaissance;
River Habitat Survey; Diatom sampling; Macroinvertebrate sampling;
Vegetation sampling
33
NOTES…
34
SESSION 3B:
CATCHMENT-SCALE PLANNING
& IMPLEMENTATION
The River Nar Restoration Strategy and Plan – From sketch to implementation
J. V. HOLLOWAY1 & K. R. FISHER2 1Projects Adviser – The River Restoration Centre
2Director – KR Fisher Consultancy
An approach to improving the empirical evidence base for
biological responses to geomorphological pressures
C. BROMLEY et al.
Senior Hydromorphologist - Ecology Partnership & Development Unit, SEPA
Catchment Sensitive Farming - A voluntary approach to implementing
River Basin Management Plan measures in sensitive river catchments
A.R.J. TYTHERLEIGH et al.
Delivery Manager – England Catchment Sensitive Farming Delivery Initiative, Natural England
NOTES…
35
THE RIVER NAR RESTORATION STRATEGY AND PLAN -
FROM SKETCH TO IMPLEMENTATION
J. V. HOLLOWAY1 & K. R. FISHER
2
1Projects Adviser – The River Restoration Centre, Cranfield Campus, Cranfield, Bedfordshire, MK43 0AL
[email protected] 2Director – KR Fisher Consultancy
The River Nar originates as a spring-fed stream west of Mileham in Norfolk, and discharges
into the Great Ouse 42 km downstream at King‟s Lynn. The river has been designated as a
Site of Special Scientific Interest (SSSI), and supports a range of important Biodiversity
Action Plan habitats, including chalk stream areas, fens, wet meadows and woodlands. The
two distinct parts of the river are managed separately: the upper „classic chalk stream‟ by the
Norfolk Rivers Internal Drainage Board (IDB, part of the Water Management Alliance); and
the lower „fen drain‟ by the Environment Agency (EA).
In 2004/5, the SSSI being in „unfavourable condition‟, Natural England commissioned a
Fluvial Audit on the Nar SSSI (Sear et al, 2006), in partnership with the EA and the IDB. The
Drainage Board undertook a study in early 2008 into the Water Control Structures in the
Upper Nar, and a similar study on structures in the Lower Nar by the EA was completed in
April 2009 (Fisher et al, 2009). Natural England was keen that the next step was to produce a
river restoration plan for the whole of the River Nar, as a „remedy‟ under the Government‟s
Public Service Agreement (PSA3) to bring 95% of all SSSIs in England into favourable
condition by the end of 2010. The project was led by the IDB in partnership with the EA,
with major inputs from RRC and KR Fisher Consultancy.
The River Nar Restoration Strategy and Plan presents measures for improving the status of
the river, with benefits for wildlife, recreation, flood risk, water quality and the landscape, by:
Presenting a complete assessment of the current state of the river, drawing together all
currently available information and findings of a dedicated survey;
Development of a vision of the ideal future condition of the Nar;
Identification of the issues which need to be addressed in order to realize this vision;
Presentation of solutions to these issues both on a whole river and a reach-by-reach
scale, while highlighting the major constraints on what can be implemented and
suggesting delivery mechanisms by which some of these solutions may be achieved.
The plan also identified five pilot projects and three of these were implemented last month.
This presentation explores the process undertaken in producing the strategy including:
developing the vision; establishing the team; the walkover survey and consultation with
stakeholders and the wider public. The successes and problems encountered within the
project process will be discussed, including the delivery of pilot projects and some of the
challenges for the future.
Keywords: SSSI; Protected area objectives; Water Framework Directive;
Ecologically-based restoration visions
36
AN APPROACH TO IMPROVING THE EMPIRICAL EVIDENCE BASE FOR
BIOLOGICAL RESPONSES TO GEOMORPHOLOGICAL PRESSURES
C. BROMLEY1, F. CARSE
2, W. DUNCAN
3
1Senior Hydromorphologist - Ecology Partnership & Development Unit, Scottish Environment Protection
Agency, [email protected] 2 Senior Environmental Modeller & Data Analyst, Environmental Assessment Unit, , Scottish Environment
Protection Agency 3 Unit Manager - Ecology Partnership & Development Unit, Scottish Environment Protection Agency
Abstract The overall aim of the Water Framework Directive (WFD) is to improve the structure and
functioning of aquatic ecosystems, with a view to protecting and enhancing the living
components of those systems. The condition of biological quality elements (BQE) (fish,
invertebrates, macrophytes and phytobenthos and phytoplankton) must therefore be classified
into one of five ecological status categories (High, Good, Moderate, Poor or Bad). The
condition of the hydrological and geomorphological quality elements must be classified and
reported on to Europe only when they are at High status; below this, they must only be of
sufficient quality to support the BQE conditions at the specified ecological status classes. This
nevertheless requires that the absolute condition of the hydrology and geomorphology is
known since, if it is not, it is not possible to determine whether or not it is providing the
required level of support. Ideally, the level of support would be assessed through biological
classification tools that are sensitive to these quality elements, but these tools are not yet
available.
The development of geomorphologically-sensitive biological classification tools is currently
hindered by an insufficiently detailed understanding of how biology responds to
geomorphological pressures. The UK Technical Advisory Group (UKTAG) has told the
environment agencies that they must develop a greater empirical understanding of these
interactions as an intermediate step towards the development of the required tools. An
approach to improving the empirical knowledge base has been identified and is described. In
essence, it is a hypothesis-driven examination of existing literature, existing biological and
geomorphological datasets, and collection of new biological and geomorphological data.
Hypotheses are developed based on detailed considerations of the mechanisms by which
certain kinds of geomorphological channel modifications impact geomorphological processes
and the ways in which in-channel biota will subsequently be impacted. Biological and
geomorphological data must be collected at spatial and temporal scales that will allow the
details of these mechanisms to be quantified.
Keywords: Water Framework Directive; Biological Quality Elements;
Mechanisms; Hypotheses; Literature review; Data re-analysis;
Data collection; Scale
37
CATCHMENT SENSITIVE FARMING -
A VOLUNTARY APPROACH TO IMPLEMENTING RIVER BASIN
MANAGEMENT PLAN MEASURES IN SENSITIVE RIVER CATCHMENTS
A.R.J. TYTHERLEIGH1, P. SMITH
2 & A.J. BURN
3
1Delivery Manager – England Catchment Sensitive Farming Delivery Initiative, Natural England, Exeter
EX4 3AW [email protected] 2Evidence Manager – Catchment Sensitive Farming, Environment Agency, Preston PR5 8BX
3Principal Specialist, Freshwater and Pollution – Natural England, Peterborough PE1 1XN
Abstract
In 2003 the then English Nature reported that diffuse agricultural pollution was of widespread
concern in England, with 72 of 156 (46%) of English river catchments containing SSSIs
considered to be impacted by or at risk from diffuse agricultural pollution (English Nature
report 551 – 2003), eutrophication being a particular problem. In addition to nutrient and soil
particle pollution, organic pollution from farms remains a serious issue for many river SSSIs.
More recent estimates from the Environment Agency‟s Water Framework Directive evidence,
suggest that approximately 40% of water bodies in England are failing to meet Good
Ecological Status with agriculture (sediments, nutrients and pesticides) cited as a major factor
and the resulting environmental damage costing between £322 - £627m per annum.
Between 2006 and 2011 the England Catchment Sensitive Farming Delivery Initiative
(ECSFDI), a partnership project between Defra, the Environment Agency and Natural
England, has had the primary aim of reducing diffuse water pollution from agriculture
(DWPA) within 50 priority catchments across England using a voluntary approach. The
ECSDFI is a key measure included in River Basin Management Plans to reduce DWPA.
The achievements of the ECSFDI Phases 1 and 2 will be presented, focusing around four
strategic objectives:
Farmer engagement and awareness, including the key lessons learnt from the range of
approaches adopted by Catchment Sensitive Farming Officers and the use of local
evidence.
The uptake of voluntary action to mitigate DWPA by farmers.
The contribution to Water Framework Directive requirements through water quality
modelling and monitoring.
The synergy and integration with related stakeholder programmes and approaches to
tackling DWPA demonstrated through National and Regional Strategic Partnerships,
including linking with the Nitrate Vulnerable Zones advice programme, Environmental
Stewardship, the Environment Agency‟s new approach to catchment based planning and
Defra‟s Demonstration Test Catchments.
Other actions proposed for Phase 3 of the CSF project (2011 to 2013) and those needed to
achieve the necessary changes in land management will be discussed, as well as requirements
to deal with other sources of pollution including small, un-consented point sources.
Keywords: Agriculture; Diffuse water pollution; Incentives; Advice; ECSFDI;
Freshwater, stakeholder engagement.
38
NOTES…
39
SESSION 4A:
SEDIMENT DYNAMICS AND FLOODPLAINS
Recreating an anastomosing channel on the River Trent at Croxall Lakes
G. L. HERITAGE et al.
Technical Director – JBA Consulting
A framework for hydrological connectivity management and site suitability
for delivery of simultaneous ecosystem services on a floodplain
N. TAKTIKOS et al.
Postgraduate Researcher – Cranfield University
Targeting excessive fine sediment in rural river systems -
The rural sediment tracing project
C. MILLS et al.
Aquatic Scientist – APEM
NOTES…
40
RECREATING AN ANASTOMOSING CHANNEL
ON THE RIVER TRENT AT CROXALL LAKES
G. L. HERITAGE1, N. S. ENTWISTLE
2 & R. KIBBLE
3
1Technical Director – JBA Consulting, The Brew House, Wilderspool Park, Greenall's Avenue, Warrington
WA4 6HL [email protected] 2Lecturer – Built and Human Environment Research Institute, Salford University, Manchester
3Masters student – Built and Human Environment Research Institute, Salford University, Manchester
Abstract
The tendency of the River Trent and its principal tributaries to split to create gravel shoals and
larger stable islands has been noted by a number of previous studies, and the resultant
geomorphic variability is seen as very important from a biodiversity perspective. This is
particularly the case as the river is highly modified with long sections of the river now stable,
morphologically uninteresting and unconnected with their floodplain.
The process of shoaling, bar and island development is primarily controlled by flow transport
variation with wider shallower reaches exhibiting sediment build up. Such reduced energy
zones may be artificially created through channel widening, scalping the floodplain silts to
expose the gravels beneath and allowing the river to rework this material together with any
inputs delivered from upstream.
Staffordshire Wildlife Trust has widened the channel of the Trent in the vicinity of the
confluence of the River Tame removing approximately 45,000 m3 of floodplain deposits.
Segmented 1D flow modelling based on surveyed cross-sections and terrestrial LiDAR survey
data suggested that a multiple channel variable height island configuration would maximise
hydromorphic diversity through the reach and maintain fine sediment transport through the
majority of channels during elevated flows. This pattern was followed during excavation.
Excavated gravels were retained and island areas left undredged to create a series of
interconnecting shallow channels. Gravel shoaling and island development is being further
encouraged through the creation of large woody debris deposits.
A hydromorphological audit of the site after one winter flow season reveals a high flow
diversity with variable erosion and deposition creating a complex pattern of biotopes. Large
woody debris has trapped gravels and additional vegetation, encouraging island formation and
gravel shoals have remained largely sediment free.
Keywords: Hydromorphology; Geomorphology; Floodplain; Anastomosed;
Upland river
41
A FRAMEWORK FOR HYDROLOGICAL CONNECTIVITY
MANAGEMENT AND SITE SUITABILITY FOR DELIVERY OF
SIMULTANEOUS ECOSYSTEM SERVICES ON A FLOODPLAIN
N. TAKTIKOS1, T.M. HESS
2 & A.B. GILL
3
1Postgraduate Researcher – Cranfield University, Natural Resources Department, School of Applied Sciences,
College Road, Cranfield, Bedfordshire MK43 0AL [email protected] 2Reader in Water Management – Cranfield University, Natural Resources Department 3Lecturer in Aquatic Ecology – Cranfield University, Natural Resources Department
Abstract
A river floodplain is one of many distinctive landscapes that can provide a range of multiple
ecosystem services due to their environmental characteristics. Throughout the course of
history, society has derived socio-economic benefits from this landscape and ecosystem e.g.
agriculture, habitation and recreation.
Anthropogenic activity has led to unprecedented alteration and modification of this landscape.
While such changes have led to improvements in the quality of life, accelerating human needs
have concomitantly weakened and degraded the floodplains‟ natural capacity to deliver and
provide benefits. Past management of floodplains placed emphasis on a single ecosystem
service that can impact on the supply of other services. The value of the floodplain ecosystem
is largely underestimated and the challenge remains to protect the ecosystem for the provision
of well-being as part of sustainable development.
This research aims to provide a framework for the management of river floodplain
hydrological connectivity and site suitability to deliver simultaneous ecosystem services.
Combined 1D/2D hydrodynamic and water balance models are used to simulate hydrological
connectivity and seasonality scenarios. The output of these scenarios will be utilized to assess
the potential for synergy and conflict amongst the identified floodplain hydrology based
ecosystem services. A range of contrasting case study sites based within the Lower Bedford
Ouse, UK, demonstrate how site characteristics can influence the delivery of hydrology based
ecosystem services.
Keywords: Floodplain; Ecosystem services; Hydrological connectivity; Models
42
TARGETING EXCESSIVE FINE SEDIMENT IN RURAL RIVER SYSTEMS -
THE RURAL SEDIMENT TRACING PROJECT
C. MILLS1, P. DENNIS
2, R.P. SMITH
3 & D.C. BRADLEY
4
1Aquatic Scientist – APEM Ltd., Riverview, A17 Embankment Business Park, Heaton Mersey, Stockport
SK4 3GN [email protected] 2Senior Aquatic Ecologist – APEM Ltd., Heaton Mersey, Stockport
3Principal Officer, Land Quality – Environment Agency, Manley House, Kestrel Way Exeter, Devon, EX2 7LQ
4Principal Aquatic Ecologist – APEM Ltd., Heaton Mersey, Stockport
Abstract
Excessive fine sediment is recognised as a limitation to the attainment of good ecological
status, or potential, by rivers in England as required by the Water Framework Directive
(WFD). However, an evidence base for the scale and magnitude of the problems associated
with excessive fine sediment inputs in English river catchments is lacking. To address this, in
2009 the Environment Agency (EA) initiated the Rural Sediment Tracing Project. The aims of
the project were: i) to devise a standardised walkover survey methodology, complimented by
aerial surveillance; and ii) to use this methodology to identify and classify sources of fine
sediment inputs to streams and rivers in 11 catchments in rural areas across England.
Excessive inputs of fine sediment were known to be a problem in the selected rivers, which
also support valuable populations of Atlantic salmon.
Walkover surveys of up to 300 km of river length were performed in each catchment by teams
of field scientists. Potential sediment sources were mapped and graded according to their
severity and origin, using a standardised methodology developed by APEM. In four
catchments the most severe sources were revisited during high magnitude rainfall events and
water samples were collected to quantify the concentrations of suspended solids upstream,
downstream and at the source of sediment inputs during runoff events. Aerial surveillance
was carried out following wet weather, to provide further evidence of sediment sources.
The ambitious survey generated an unprecedented data set, which identified sediment from
agricultural sources as the major contribution to the problem of excessive fine sediment in
these catchments. The dominant types of fine sediment source were from livestock poaching
and runoff from arable land. In addition, sediment runoff from roads, tracks, field drains and
bank works constituted a significant input in most of the catchments surveyed. The severity of
fine sediment input in a given catchment was found to be dependent on the intensity of
agriculture in combination with the underlying erosion risk of the soil.
Potential ecological damage, often in the form of sedimentation of valuable salmonid habitat,
was observed in every catchment. Within catchments there were often specific tributaries or
localised areas where the effects of excessive fine sediment were most obvious. We discuss
the results of the survey and their implications for the restoration of riverine habitats. The
survey results provide the basis for a targeted approach to tackling the problem of elevated
fine sediment levels at source by identifying the specific areas that are contributing most to
the problem in each catchment.
Keywords: Agricultural runoff; diffuse pollution; Water Framework Directive
43
NOTES…
44
SESSION 4B:
CONTEMPORARY APPROACHES TO
IN-STREAM BARRIERS
In stream barriers assessment – A multidisciplinary approach
J. SHAW et al.
Environmental Scientist – Atkins
Weir removal assessment and evidence base
J. MANT et al.
Science & Technical Manager – The River Restoration Centre
A simple way to ease fish and eel passage across a sluice apron
M. PORTER et al.
Project Officer – Environment Agency, South West Region
NOTES…
45
IN STREAM BARRIERS ASSESSMENT –
A MULTIDISCIPLINARY APPROACH
J. SHAW1, K. SKINNER
2, A. HUMPHREYS
3 & R. SEWELL
4
1Environmental Scientist – Atkins, The Hub, 500 Park Avenue, Atzec West, Almondsbury, Bristol, BS32
4RZ [email protected] 2Principal Consultant, Hydromorphology and River Restoration/Management – Atkins, Oxford
3Senior Engineer, Rivers and Coastal – Atkins, Swansea 4Assistant Environmental Scientist, Rivers and Coastal – Atkins, Glasgow
Abstract Instream barriers are a major obstacle for fish migration. The removal or modification of these
structures is widely seen as a substantial environmental gain in the first round of River Basin
Management Plans under the Water Framework Directive (WFD). Large scale surveys undertaken by
the various statutory authorities have identified the location of many of these structures around UK
rivers. For example, the Environment Agency has estimated that there are approximately 26,000 of
these features throughout England and Wales. The current challenge is to prioritise catchments and to
assess the identified structures to establish whether it is both technically and practically feasible to
remove or modify them to improve the hydromorphological and ecological functioning of the river
system.
This paper presents a multidisciplinary, integrated barrier assessment methodology that has been
developed by Atkins and successfully applied on 40 sites for the Environment Agency and the Scottish
Environment Protection Agency (SEPA). The rapid-style assessments included desk-based study and
a site visit. Importantly, a range of linked factors were considered at each site. These included
environmental factors such as terrestrial ecology, fisheries, hydromorphology and human-related
factors such as engineering design and site access. Baseline conditions for each were recorded at the
barrier sites themselves, and also along the upstream and downstream reaches to estimate the spatial
zones over which the barrier was currently having an impact. This information was used as the basis
for consultation within the Atkins team and with the client to identify the most suitable management
option for each barrier based on potential risks versus environmental benefits and technical feasibility.
The options considered included i) do-nothing, ii) full removal, iii) partial removal, iv) formal fish
pass and v) an informal or easement-type fish pass. After appraising each of the options and
considering the technical feasibility of structural works, costs and impacts on flooding, an option was
recommended and monitoring and mitigation recommendations were made. In certain cases,
additional assessment works were recommended for the detailed design phase. For each barrier, the
data and accompanying assessment were presented in a simple, structured format with photographs to
provide a consistent and user-friendly output to the client and stakeholders.
The paper also presents case studies from the projects and examines the main constraints to
recommending the WFD preferred option of full barrier removal. Alternative options that could be
scoped into the works are also discussed.
Keywords: Water Framework Directive; Fish passage; Fish pass; Barrier removal;
Barrier modification; Options appraisal; Integrated approach
46
WEIR REMOVAL ASSESSMENT AND EVIDENCE BASE
J. MANT1, N. D. ELBOURNE
2 & A. T. PEPPER
3
1Science & Technical Manager – The River Restoration Centre, Cranfield Campus, Cranfield, Bedfordshire,
MK43 0AL [email protected] 2Information Officer – The River Restoration Centre
3Director – ATPEC River Engineering Consultancy
Abstract For centuries, weirs have been constructed across rivers to fulfil a wide variety of aims, including
power generation (milling or hydro), navigation, irrigation, angling, flow measurement or amenity.
Many weirs no longer fulfil their original function and may be considered for removal in order to
restore the river to a more natural state, as each weir will have altered the geomorphology of the river
in its vicinity.
However, there is still concern about where and when it is appropriate to remove a weir. For instance,
a weir constructed to impound water for a mill may create a wide expanse of water upstream,
appreciated by the local population for its aesthetics, its angling and the ducks which inhabit it.
Removal of that same weir could create a narrow, fast flowing stream flanked by muddy banks which
would quickly become covered heavy marginal vegetation. Whilst this may be an improvement in
habitat for some species the general public may consider it to be less attractive. In more dynamic
systems, concerns about bank stability upstream are often cited as a reason for not removing a weir.
The River Restoration Centre completed a review of weir removal projects for the Environment
Agency, based on data held on the Centre‟s National River Restoration Inventory and follow-up
questionnaires. The aim was to provide information to increase the evidence base of weir removal
success and hence reduce the current level of uncertainty associated with removal.
This paper will provide a summary of the information collected and, through a series of case studies,
outline what are the key elements that need to be considered when removing a weir.
Keywords: Bank erosion; Bank protection; Literature review; Guidance; Case study
evidence
47
A SIMPLE WAY TO EASE FISH AND EEL PASSAGE
ACROSS A SLUICE APRON
M. PORTER1, A. MARTIN
2 & A. FRASER
3
1Project Officer – Environment Agency, Rivers House, Sunrise Business Park, Blandford Forum, DT11 8ST
[email protected] 2Fisheries Technical Specialist – Environment Agency, Blandford Forum
3PSA Delivery Officer – Environment Agency, Blandford Forum
Abstract
The Water Level Management Plan (WLMP) programme has delivered over £4 million worth
of improvements in the Wessex area. Its main focus, The River Avon System SSSI and SAC
is designated for Ranunculus vegetation, Atlantic salmon, sea and brook lamprey, bullhead
and Desmoulin‟s whorl snail, and was largely in unfavourable condition due in part to water
level management issues. The WLMP programme has greatly improved conditions for SSSI
species by reviewing the apportionment and impoundment of water and taking appropriate
action to reach favourable/recovering condition through extensive works on the ground.
One such example, Ashley Stream Hatches, controls flow apportionment between Ashley and
King Streams, both part of the SSSI and SAC. The structure is 450m downstream of an open
offtake from the main Avon, and comprises three large sluices which were in a poor state of
repair, hampering operation and affecting the flow regime and habitat quality in these
important fisheries channels. The structure‟s apron is 5x4 m wide, and under low flow
conditions, impeded upstream fish and eel passage owing to the shallow depth of water and
the ~0.5m metre difference in levels between the apron and the weir pool. Cost and land
management issues discounted total removal, so a range of solutions were considered to make
the structure passable, whilst maintaining its operation. Due to the site‟s location within the
Avon Valley and New Forest, the solution had to be in-keeping with its surroundings. The
preferred option was to refurbish the existing hatches to a safe operable condition and use
natural and site-won materials to ease fish and eel passage.
This was achieved by creating a ponded area on the concrete apron to increase the depth of
water flowing over it. A semi-circular adherent nappe on the apron face also helps upstream
passage during low flows. It was necessary to raise levels in the downstream weir pool to
bring them closer to that of the weir apron, which was done by the installation of three
notched log weirs downstream of the pool, using site-won timber and local gravel. These
were big enough to be tied into the bank and stream bed to ensure they are sufficiently
watertight so as not to create a further barrier to fish.
This solution has a limited lifespan (10-20 yrs), but in the meantime provides a comparatively
quick (3 weeks), cheap (£30k) and low-carbon-footprint solution to easing passage, without
preventing future installation of a more engineered pass or structure removal at a later date.
Keywords: Low cost; Low carbon; Fish passage; Log weirs; Weir bypass
48
NOTES…
49
SESSION 5
Restoring rivers – The challenges of implementing whole-river plans and
implications for the wider river network
JENNY WHEELDON
River restoration Specialist – Natural England/Environment Agency
NOTES…
50
SESSION 6:
PARTNERSHIP WORKING & LOCAL ENGAGEMENT
Partnerships for river restoration - More for less?
RUTH NEEDHAM et al.
Project Manager – OnTrent
How the Thames won the 2010 International Riverprize
ALASTAIR DRIVER
National Conservation Manager – Environment Agency
Development of a Water Framework Directive-driven
restoration strategy for the River Trent
D. FRASER et al.
Principal Scientist – APEM
NOTES…
51
PARTNERSHIPS FOR RIVER RESTORATION - MORE FOR LESS?
RUTH NEEDHAM1, JULIE WOZNICZKA
2 & TIM PICKERING
3
1 OnTrent Project Manager – The Wolseley Centre, Wolseley Bridge, Stafford, ST17 0WT
[email protected] 2OnTrent Project Manager – The Wolseley Centre, Wolseley Bridge, Stafford, ST17 0WT
3Technical Specialist, Strategic & Devt. Planning – Environment Agency, Midlands Region, Sapphire, Solihull
Abstract
The Trent‟s catchment occupies 8% of England and passes through over 21 local authority
areas, yet many feel that it is one of England‟s major „forgotten rivers‟. The OnTrent
Initiative is a partnership with the vision of „a Trent landscape, rich in wildlife habitats,
landscape and historic features for the benefit of all, both now and in the future‟. Our core
work is about adding value and capacity building – it‟s about developing projects and policy
from ideas to reality. Now well established, OnTrent has been informing strategy and
initiating projects in the valley and wider catchment since 2002. There are now landscape-
scale projects delivering wetland and river based work throughout the entire Trent corridor,
with benefits including a long distance path, mapping; enhancement of the landscape, historic
environment, communities and biodiversity; as well as training and seminars.
National policy which has increasingly promoted wider, coordinated management, such as the
Catchment Flood Management Plan, River Basin Management Plan and the Flood and Water
Management Act 2010, all provide a formal route for new partners, in particular Local
Authorities, to become more involved with water management at a catchment or sub-
catchment scale. However, increasingly restricted funding is forcing resources to become
almost entirely target driven. A lack of core funding limits the ability of partner organisations
to be involved with strategic work and makes supporting such an extensive network of
projects and partners particularly challenging.
This seminar will discuss such threats, future priorities and opportunities for OnTrent and
similar initiatives. It will examine whether partnerships across a river catchment really can
deliver more for less. With government agencies more likely to be restricted to core functions
in coming years, it is suggested that alliances such as these may have the flexibility to identify
gaps and exploit opportunities to work innovatively across sectors.
In particular, OnTrent plans to support Farming and Water for the Future (projects across the
catchment to store flood water on farmland); further development of the Trent Valley Way;
Blue Infrastructure enhancement (working with local authorities); and large scale restoration
plans, particularly as part of aggregate extraction mitigation amongst others. It is recognized
that the partnership will need to be adaptable and resilient, able to take on new projects and
deliver; be more creative than ever about how to access and use funding from a range of
sources; and find ways to engage more effectively with both the commercial sector and local
authorities.
We consider that OnTrent has many strengths but would greatly benefit from a more
coordinated national approach to support it and other catchment based partnership projects.
Keywords: Integrated catchment management; Multiple benefits; Flooding;
Green infrastructure; Biodiversity; Access
52
HOW THE THAMES WON THE 2010 INTERNATIONAL RIVERPRIZE
ALASTAIR DRIVER
National Conservation Manager – Environment Agency, Kings Meadow House, Reading, Berks. RG1 8DQ
Abstract
The A$350,000 International Thiess Riverprize is the world‟s largest environmental prize and
it celebrates outstanding achievements in river management and restoration. It is awarded
each year at the International Riversymposium in Australia and gives an incentive to further
worldwide efforts to repair damaged rivers and waterways. It also celebrates world best
practice in the stewardship of rivers. The Riverprize is a partnership between the International
Riverfoundation and the International Riversymposium.
In 2010, the Environment Agency submitted a successful bid for the River Thames to win the
prize, on behalf of thousands of people from hundreds of organisations who have worked
tirelessly to restore the river and its catchment over the last 50 years. The Thames was
selected out of a record number of entries and in the final it was up against the world-famous
and three times finalist, Yellow River (China), Hattah Lakes (Australia), and the Smirnykh
Rivers Partnership (Russia).
Pollution of the tidal Thames left it biologically dead in the 1950s, but since then the river has
been transformed into a thriving ecosystem teeming with fish, and with returning sea trout
and otter populations. However, the prize submission acknowledged that there is still much
work to be done to continue improving the quality of the river – especially the tidal Thames
and its tributaries in London.
The Environment Agency‟s submission focused on 5 wide-ranging projects to demonstrate
the innovative and challenging solutions now underway to achieve this further improvement:
Catchment Sensitive Farming: working with farmers to reduce rural diffuse pollution
from nutrients and pesticides.
The Jubilee River flood alleviation scheme: creating a new 11 km stretch of naturalistic
river and habitats, whilst delivering flood protection to 5,500 homes.
The London Rivers Action Plan: helping restore London‟s urban rivers, with 58 new
river restoration projects in progress since its launch in 2009.
The London Tideway Tunnels: a £3.6bn+ scheme tackling the 39 million tonnes of
untreated sewage flushed into the Thames by storms in a typical year.
Thames Estuary 2100: a 100-year adaptable plan directing the future sustainable
management of tidal flood risk in the Thames estuary, and protecting over 1.25million
people and £200bn in property value.
Keywords: Restoration; Catchment; Partnership
53
DEVELOPMENT OF A WATER FRAMEWORK DIRECTIVE-DRIVEN
RESTORATION STRATEGY FOR THE RIVER TRENT
D. FRASER1, M. TURNER
2 & D.R. JOHNSON
3
1Principal Scientist – APEM Ltd, Centre for Innovation and Enterprise, Oxford University Begbroke Science
Park, Sandy Lane, Yarnton OX5 1PF [email protected] 2Consultant Scientist – APEM Ltd, Yarnton
3Fisheries Technical Officer – Environment Agency, Lichfield, Staffordshire
Abstract
APEM Ltd was commissioned by the Environment Agency to develop a strategic programme
of prioritised river restoration measures on the River Trent, from Stoke-on-Trent to the
confluence with the River Sow at Great Haywood. The primary objective of the programme is
to address factors currently constraining Water Framework Directive (WFD) Good Ecological
Status on the two WFD water bodies which comprise this 40 km reach.
Initial appraisal of both hydromorphological and biological elements was undertaken to
inform restoration options. Hydromorphological elements were appraised via a
comprehensive walkover survey encompassing fisheries habitat survey, mapping of physical
modifications and impacts (including barriers to fish migration) and sediment tracing
techniques previously developed by APEM to identify diffuse pollution pathways and
sources. Ecological elements were obtained from a combination of existing EA records
(invertebrates, macrophytes, River Habitat Survey and water quality) and a bespoke
comprehensive survey of fish undertaken by APEM. The requirement to identify physical
factors likely to constrain angling participation was an additional social and recreational
element of the project.
Key constraints will be determined via the assembled hydromorphological and ecological
data. This in turn will enable restoration measures designed to alleviate these constraints to be
provisionally identified.
The ultimate objective will be production of a prioritised list of restoration actions, which will
serve as a medium term programme of work for the Environment Agency and partners.
Production of such a list will entail the development of a prioritisation system, which will be
based on benefits envisaged, most notably in terms of WFD, but also in terms of other
statutory and local drivers (e.g. Eel Management Plans and recreational angling) and benefits
and desirability amongst stakeholders versus costs of measures. Given the need for broad
stakeholder support to facilitate and deliver the programme, stakeholder consultation on the
provisional list of measures is a core element of the project, and will be key in prioritising and
finalising the measures.
Keywords: Strategic restoration; Prioritisation; Stakeholder; Fisheries; Walkover
54
NOTES…
55
SESSION 7A:
NOTT FAR FROM NOTTINGHAM
“Trout in the Town” - Urban river restoration and promotion
by local community groups
P. N. GASKELL
Programme Manager: “Trout in the Town” – The Wild Trout Trust
Assessing the past for the future:
A case study of Nottinghamshire's forgotten water meadows
J. HILLMAN et al.
Senior Soil and Water Scientist – URS-Scott Wilson
Restoration of riparian habitats on the old course of the River Ise
in Northamptonshire
R.G. FIELD et al.
Revital-ISE Project Manager – River Nene Regional Park CiC
NOTES…
56
“TROUT IN THE TOWN”
URBAN RIVER RESTORATION AND PROMOTION
BY LOCAL COMMUNITY GROUPS
P. N. GASKELL
Programme Manager: “Trout in the Town” – The Wild Trout Trust, PO Box 120, Waterlooville PO8 0WZ
Abstract
Trout in the Town is a UK-wide project launched by the Wild Trout Trust in 2008 to
engender local community custodianship, education and engagement with restoration of urban
rivers. Two branches of this project close to Nottingham are the River Erewash (River
Erewash Foundation, Notts.) and the River Don (SPRITE, South Yorks.). The project has also
delivered classroom and outdoor educational activities promoting healthy rivers and
responsible water-use in the Staffordshire area.
Dramatic improvements to water quality in recent decades mean that pollution-sensitive
species of fish, invertebrates and plants are, again, colonising our urban river corridors.
However, local human populations often remain wedded to lifelong precepts that their urban
watercourses are dirty and lifeless. This situation is often compounded by the prevalence of
fly-tipping in urban watercourses that seems to confirm a “polluted” verdict to the casual
observer.
Here, I outline relevant case study examples of the challenges and progress of local groups in
tackling both the biological and sociological issues encountered by volunteer-group urban
river restoration efforts.
Keywords: Biodiversity; Education; Engagement; Custodians
57
ASSESSING THE PAST FOR THE FUTURE: A CASE STUDY OF
NOTTINGHAMSHIRE'S FORGOTTEN WATER MEADOWS
J. HILLMAN1, S. LAMBERT
2, K. STEARNE
3, B. DUNNING
4 & R. BOWER
5
1Senior Soil and Water Scientist – URS-Scott Wilson, Nottingham [email protected]
2LIS Project Officer – Nottinghamshire County Council, Trent Bridge House, West Bridgford, Nottingham
3Water Meadow Advisor – Natural England, Victoria House, Cross Lanes, Guildford, Surrey
4Land Management and Conservation Advisor – Natural England, Ceres House, Lincoln
5Tenant – Manor Farm, Carburton, Nr. Worksop, Nottinghamshire
Abstract
A water meadow is a man-made pasture irrigation system, aiming either to increase total grass
production or bring it forward in the year, by irrigating „panes‟ of grass with shallow flowing
water. The water, warmer than the surrounding soil, allows growth during winter months,
with the added benefits of nutrients, readily available oxygen and a liming effect.
Water Meadows are part of Nottinghamshire‟s rural history, dating to the 19th Century;
generally forgotten, but within living memory of local communities. Research has re-
discovered large areas of meadows in the Maun, Meden and Poulter Valleys, as well as other
smaller systems. The Estates of the Dukeries were responsible for considerable water
engineering, including the 125 ha Clipstone meadows on the Maun. Despite widespread
historical area, water meadows suffered post-war decline, going out of use in the late 1960‟s.
Nottinghamshire‟s little known „catchwork‟ systems, now a generally neglected relic of the
landscape, contrast with southern England‟s well researched, documented and sometimes
preserved „bedwork‟ systems, where soils, geology and climate are also quite different.
There are many potential benefits from restoration of these low input agricultural systems,
including additional areas of priority wet grassland habitat for the county, encouraging
wading birds; trapping sediment and adsorbed phosphorus; and education potential. All these
benefits can be delivered through Higher Level Scheme (HLS) funding.
This presentation describes work to begin to select a Nottinghamshire water meadow for
restoration, which uncovered several previously forgotten sites. Work to characterise the
functioning of the system is also discussed, which led to a number of historic features being
unearthed following aerial and ground-based survey, plus research into historical documents.
During 2010, a pilot area was restored using, as far as possible, historically accurate methods.
A management plan was also drafted for the remaining site, primarily aimed at creating wet
grassland habitat, but also allowing controlled access to view key features.
A key research finding has been the sheer area of undocumented water meadows in
Nottinghamshire and the Midlands. Though many systems are beyond restoration, even sites
impacted by subsidence could have a key role to play in delivering environmental objectives.
Keywords: Water meadow; Nottinghamshire; Wet grassland; Water quality;
Habitat; Catchwork; Restoration; Agri-environment; Education
58
RESTORATION OF RIPARIAN HABITATS ON THE OLD COURSE OF THE
RIVER ISE IN NORTHAMPTONSHIRE
R.G. FIELD1, N. MONAGHAN
2 & J. PEARMAN
3
1Revital-ISE Project Manager – River Nene Regional Park CiC, John Dryden House, 8-10 The Lakes,
Northampton, NN4 7DE, 01604-237243 Email: [email protected] 2Project Officer – River Nene Regional Park CiC, John Dryden House, Northampton
3Reserves Manager – Northamptonshire Wildlife Trust, Lings House, Billings Lings, Northampton, NN3 8BE
Abstract
Within the last 100 years much of the course of the River Ise in Northamptonshire has been
modified. Most of the cornmills and associated water features have disappeared or, as with the
water meadows at Wicksteed, have become disconnected from the main river. Several areas
where the old meanders remain next to the river were Local Wildlife Sites (LWS), but in
some cases as succession took place these areas lost their botanical interest. The Revital-ISE
Project, which started in 2008, has been instrumental in the campaign to restore these features
and three sites have been specifically targeted. It is hoped that once restored some of these
sites will be managed by the local communities and as such a new community group called
„Natural-ISE‟ has been formed.
The first site was the Wildlife Trust reserve at Tailby Meadows, Desborough, while the
second was at the „Ise Valley Park‟ in Kettering. Just below those sites in Kettering is the
third site which is a remnant of the water meadow system which was found down the Ise
valley. This site which is approximately 7ha in size is being restored to its former glory.
In a separate initiative a range of training events have been held at a local field centre for
groups of local volunteers. These covered many aspects of managing and surveying the
countryside. These volunteers will then hopefully be able to manage their own local sites in
the future.
Keywords: Revital-ISE; Meanders; Local volunteer groups; Wet grassland;
Tailby Meadows; Community training events; Ise Valley Park
59
NOTES…
60
SESSION 7B:
PARTNERSHIPS GREAT & SMALL
3 Rivers clean up – Ravensbourne catchment SE London
A partnership approach to invasive species removal on a catchment scale
VICTOR RICHARDSON et al.
SE London River Programmes Coordinator – Thames21
Partnership works in Northern Ireland - Always start with a cup of tea
J. BANKHEAD & G. GREER
Conservation Officers – Rivers Agency, Belfast
The role of self-help groups in river flood management
J. SIMM
Technical Director – HR Wallingford
NOTES…
61
3 RIVERS CLEAN UP – RAVENSBOURNE CATCHMENT SE LONDON
A PARTNERSHIP APPROACH TO INVASIVE SPECIES REMOVAL
ON A CATCHMENT SCALE
VICTOR RICHARDSON1, MATTHEW BLUMNER
2 & CHRIS MCGAW
3
1SE London River Programmes Coordinator – Thames21, Walbrook Wharf, Upper Thames St, London
EC4R 3TD [email protected] 2Founder Member – Quaggy Waterways Action Group, c/o 86 Lewisham Hill, London SE13 7EL
3Rivers & People Officer – Lewisham Council
Abstract
The eradication of invasive non-native species from riverine habitats is a long labourious task
and needs a stratgegic approach to tackle the issue effectively. Different invasive species
require different techniques for removal. At the 3 Rivers clean-up, a catchment wide
programme of events was coordinated by a range of local partners. The events involve local
volunteers manually removing Himalayan Balsam (Impatiens glandulifera) from along the
River Ravensbourne, River Pool and the Quaggy River that make up the catchment. The
project aims to effectively manage Himalayan Balsam by creating an annual programme of
activities attended by volunteers recruited from a wide range of sources including local
residents, existing friends groups, community organisations and corporate groups.
The project‟s greatest resource is the volunteers, but when looking at the Ravensbourne
catchment, some areas have very good support and others very little or none. Increasing
volunteering capacity over the catchment is important for the project‟s success as it will be
necessary to cover the entire river system and not just the worst affected areas. In this case,
increasing capacity on the upper reaches will be crucial to forming a more strategic approach
to removing Himalayan Balsam, source to mouth.
An added complication or asset is that the river flows through 3 London boroughs, increasing
resources and support available to the project but also complicating decision making.
However, the partnership with local authorities, local groups such as Quaggy Waterways
Action Group (QWAG), Thames21 and the Environment Agency, has worked well in
delivering this project. Perhaps the greatest outcome is the raised awareness that is now
shared with the public and the opportunity to learn more about their river systems.
Keywords: Thames21; Himalayan balsam; Volunteers; Catchment management;
QWAG; Enhancement
62
PARTNERSHIP WORKS IN NORTHERN IRELAND -
ALWAYS START WITH A CUP OF TEA
J. BANKHEAD & G. GREER
Conservation Officers – Rivers Agency, Hydebank, Hosptial Road, Belfast BT8 8JP
Abstract
Rivers Agency is the flood defence and drainage authority in Northern Ireland, and as such,
has a narrow legislative remit. Working under the Drainage Order (NI) 1973, there is no
specific permission for restorative or conservation lead works. Consequently most such work
is often carried out through partnership projects.
Partnership works tend to be based on biodiversity and enhancement, and aim to have an
additional benefit to the Agency through reduced maintenance, bank stability, etc. Rivers
Agency provide input through design, advice and provision of plant and labour, but not
through direct funding. Projects tend to be small in nature, and directed at the reach scale.
Partners include other government bodies, local councils, local interest groups and NGOs.
This seminar will present experiences from Northern Ireland, focusing on two particular
examples:
Lower Bann Erosion Project. A joint project with the Lough Neagh and Lower Bann
Advisory Committee, with works based upon bioengineering solutions to bank erosion
problems. Erosion is due to a range of factors including water sports, arterial drainage legacy,
and lack of bankside fencing. Measures used included willow faggots, coir rolls and recycled
Christmas trees. Monitoring of the project has been carried out using fixed point
photography.
Kilnatierney Managed Retreat and Wetlands Project. Situated within an ASSI and abutting a
SPA, this is a joint project with the National Trust. Work has been carried out in two distinct
phases - firstly, the creation of freshwater, winter inundation, using sluice-controlled flow
from a field edge river, and land sculpting. This was designed to encourage wintering
wildfowl, a SPA criterion. Secondly, controlled breaching of a sea defence to allow
inundation to a brackish lagoon (which was becoming increasingly fresh in character) and
encourage the rise of the Spire Snail!
Keywords: Bann; Erosion; Christmas tree; Faggots; Kilnatierney; Inundation;
Sea defence; Lagoon; Brackish; Hydrobia acuta
63
THE ROLE OF SELF-HELP GROUPS
IN RIVER FLOOD MANAGEMENT
J. SIMM
Technical Director – HR Wallingford, Howbery Park, Wallingford OX12 9UJ [email protected]
Abstract
In flood risk management, stakeholder engagement or “citizen participation” has been
endorsed at the European Level and is part of UK national policy. However, the forms of
participation now emerging in flood management go well beyond consultation and
engagement, to local funding and participation, a trend which was supported by Sir Michael
Pitt‟s report on the Summer 2007 floods and has now been strongly endorsed by the „big
society‟ theme of the new coalition government.
Alongside these changes, the pressures on limited budgets within organisations like the
Environment Agency and prioritisation of maintenance work has meant that the service that
smaller (often rural) communities have come to expect is unlikely to continue. Many citizens
now feel that reduced levels of maintenance are contributing to an increased risk of flooding
and consequently, local flood action self-help groups are starting to form to organise
maintenance work or construct flood defences.
Based on data from semi-structured interviews and working experiences, this paper will
provide some reflections on groups within the Thames Region and on the South Coast and
will compare this with analogous experiences in environmental river management. The
discussion will cover the activities (weed cutting, dredging, defence repair/raising, etc.) and
motivations (desire to mitigate loss and reduce insurance premiums, active citizenship,
physical fitness, etc.) of these groups. The paper will also identify some barriers to voluntary
activity, including legal and insurance issues and riparian ownership and will conclude with
some reflections on the future for such groups.
Keywords: River management; Flood management; Self-help groups
64
NOTES…
65
66
POSTER PRESENTATIONS
Contrasting hydromorphological systems: Differences between engineered
and near natural reaches of the River Dee at Braemar
C. ANDERTON et al.
Senior Analyst – JBA Consulting
Catchment and local scale restoration challenges
in a high energy Scottish catchment
C. ANDERTON et al.
Senior Analyst – JBA Consulting
A new coarse resolution, rapid-assessment methodology to assess
the passability of obstacles to fish migration
C. BULL1 & C. BROMLEY2 1Senior Consultant - Centre for River EcoSystem Science, University of Stirling
2 Senior Hydromorphologist - Ecology Partnership & Development Unit, SEPA
Targeted maintenance, Mill Operating Protocols and river restoration strategy
to deliver flood risk management and Good Ecological Potential at least cost
R. A. CHASE1, & A. C. PAOLI2 1Principal River Consultant – Atkins
2Civil Engineer – Atkins
Delivering a sustainable approach to controlling invasive non-native species
on Dumfries and Galloway's Rivers
ANNE CONNICK
Catchment Management Planning Officer – SEPA
Facilitating the application of Output from REsearch and CAse STudies
on Ecological Responses to hydro-morphological degradation and rehabilitation
(FORECASTER)
I. COWX et al.
Professor of Applied Fisheries Science – University of Hull
Implementing a monster river restoration programme
JO CULLIS et al.
Principal Environmental Consultant – Halcrow
67
Building in sustainability – The use of synthetic geo-textiles in river restoration
P. F. EASTON1 & S. CAIN2 1Senior Consultant – Cain Bio-Engineering
2Managing Director – Cain Bio-Engineering
Practical River Appraisal Guidance for Monitoring Options (PRAGMO)
J. ENGLAND et al.
Environmental Monitoring Team Leader – Environment Agency
Metal concentrations in sediments within restored and un-restored London rivers
H.M. GIBBS et al.
PhD Student - School of Geography, Queen Mary, University of London
Utilising river restoration to improve water quality
D. M. HAMMOND1 & A. SCOTT2 1Senior Projects Adviser – The River Restoration Centre
2Lead Environmental Advisor – Yorkshire Water
Predicting ecological gains following assisted natural recovery:
An example from the River Ribble at Long Preston Deeps
G. L. HERITAGE1 & K. SHEEHAN2 1Technical Director – JBA Consulting
2Senior Analyst – JBA Consulting
The hydromorphological consequences of channel management:
Lessons from upland systems in the UK
G. L. HERITAGE et al.
Technical Director – JBA Consulting
An ecological vision for the River Lugg SSSI
B. LASCELLES et al.
Technical Director – Hyder Consulting
Local partnership and mechanical excavators deliver value for money and
sustainable river restoration
A. MAXWELL et al.
Water Level Management Plan Project Officer – Environment Agency, South West Region
Developing cost-effective restoration options for the Nant Mills fish pass
J. A. MOON1, & R. JONES2 1Senior Geomorphologist – Black & Veatch
2Principal Engineer – Black & Veatch
68
Morphological adjustment and ecological response to tributary reconnection
in an upland river
E. C. QUINLAN et al.
PhD student – Northern Rivers Institute, University of Aberdeen
Some simple tools for communicating the biophysical condition of urban rivers
to support high-level discussions regarding river restoration
LUCY SHUKER
PhD researcher – Queen Mary, University of London
NOTES…
69
CONTRASTING HYDROMORPHOLOGICAL SYSTEMS:
DIFFERENCES BETWEEN ENGINEERED AND NEAR NATURAL
REACHES OF THE RIVER DEE AT BRAEMAR
C. ANDERTON1, G. L. HERITAGE
2, D. MILAN
3 & S. COOKSLEY
4
1Senior Analyst – JBA Consulting, Port Neuk, Longcraig Road, South Queensferry, Edinburgh EH30 9TD
[email protected] 2Technical Director – JBA Consulting, The Brew House, Wilderspool Park, Warrington WA4 6HL
3Senior Lecturer – Department of Natural & Social Sciences, University of Gloucester, Cheltenham GL50 4AZ
4Project Officer – Dee Catchment Partnership, The Macaulay Institute, Aberdeen AB10 1YP
Abstract
The hydromorphic variation of the majority of UK rivers has been altered as a result of flow
modification, engineering works and land management. This paper looks at the effects
through the survey and mapping of two reaches of the River Dee upstream of Braemar in
Scotland.
Aerial LiDAR and Acoustic Doppler Velocity Profiling provided the baseline morphologic
and hydraulic validation data for a 2D flow model of a single thread reach subject to channel
training and an unconstrained wandering section flowing across a more natural floodplain
further upstream. The model was used to simulate a series of flows from 4 (baseline survey)
up to 100 m3s
-1 (approximately bankfull discharge) and depth and velocity data were extracted
to generate the Froude number for each wetted cell in the 2m grid cell model arrangement.
These data were then categorised according to biotope unit based on published Froude
number limits allowing biotope variety, variability and dominance to be calculated and
compared between sites for each flow.
It is clear from the results that the engineered section is generally biotope poor with low
variety and variation even at low flows. This contrasts markedly with the pattern and types of
unit modelled for the more natural reach. In contrast to previous research on more uniform
rivers there was also an increase in biotope variety as flows increased due to the activation of
chute channels and the inundation of bar surfaces to generate new hydraulic units within the
wandering channel boundary. It is clear that engineering has had a major affect on the
hydromorphology of the River Dee at both low and high flows and that this in turn has
impacted adversely on in-stream habitats and biology.
Keywords: Hydromorphology; Geomorphology; LiDAR; ADVP; Biotopes
70
CATCHMENT AND LOCAL SCALE RESTORATION CHALLENGES
IN A HIGH ENERGY SCOTTISH CATCHMENT
C. ANDERTON1, G. L. HERITAGE
2 & J. WRIGHT
3
1Senior Analyst – JBA Consulting, Port Neuk, Longcraig Road, South Queensferry, Edinburgh EH30 9TD
[email protected] 2Technical Director – JBA Consulting, The Brew House, Wilderspool Park, Warrington WA4 6HL
3Clerk – Argyll District Salmon Fishery Board, Cherry Park, Invarrary, Argyll & Bute PA32 8XE
Abstract
The Carradale Water drains a 59 km2 catchment on the eastern side of the Kintyre Peninsula,
Argyll, Scotland. It initially flows through steep confined valleys cut into resistant Schist
geology, before exiting onto a wide floodplain composed of fluvio-glacial alluvium and
discharging into the Kilbrannan Sound. Under the Water Framework Directive, the Carradale
Water is currently classified as having a moderate status, where historical drainage and
agricultural improvement activity, together with more recent local flow diversion and
catchment intensive forestation has impacted on the flow and sediment balance within the
watershed. The river is a high energy system and is presently responding to these changes
through intense local morphological adjustment. Concern exists over the currently unstable
state of the watercourse, with large scale sediment deposition and associated erosion and
channel migration affecting valuable farm land and habitats in the lower reaches. Due to the
number of stakeholders within the catchment a local working group has been formed to
address these issues and inform future catchment planning and restoration.
This paper discusses the first stage of a project designed to develop a sustainable river
management plan through a catchment management scoping study identifying the challenges,
constraints and benefits involved in the sustainable restoration of the river and its floodplain.
The study has been developed through a catchment-wide geomorphic audit and quantitative
modelling of zones of high mobility using a 2D mobile bed approach which combines
hydraulic and ecological predictions using the River2D flow model. Optioneering using the
model simulations has facilitated the development of a long term high level catchment
restoration plan linked to short and medium term local scale mitigation options to alleviate
bank erosion along presently unstable reaches. Reducing the magnitude and frequency of
spate flows, encouraging natural bar development processes and promoting chute channel
cutoff processes appears to be key to securing long term stability along the river, facilitating
riparian vegetative sediment stabilisation and allowing flood flows to be redistributed along
wooded secondary channels.
Keywords: River restoration; Geomorphology; Floodplain; 2D modelling
71
A NEW COARSE RESOLUTION, RAPID-ASSESSMENT METHODOLOGY
TO ASSESS THE PASSABILITY OF OBSTACLES TO FISH MIGRATION
C. BULL1 & C. BROMLEY
2
1Senior Consultant - Centre for River EcoSystem Science, University of Stirling
2 Senior Hydromorphologist - Ecology Partnership & Development Unit, Scottish Environment Protection
Agency, [email protected]
Abstract
A new method has been developed that provides a means of rapidly estimating the likelihood
that migratory fish of several different species will be able to pass, both upstream and
downstream, the full range of obstacles found on British rivers. Such a method is required to
improve and to extend the coverage of river fish classification for the Water Framework
Directive; to identify critical, man-made bottleneck obstacles in a catchment that can be
targeted for removal or the installation of fish passage facilities; and to help improve the
regulation of abstractions and impoundments. Existing fish data are generally not at the
spatial or temporal resolution needed to assign an estimate of passability to each obstacle and
the collection of such data is time consuming. Expert judgment assessments are thus generally
used to assign a degree of passability to obstacles. The reasons underlying an expert judgment
are frequently not recorded, or are not recorded in a consistent fashion, however, so it can be
very difficult to understand how an assessment of passability was arrived at. Using the new
method, all the data used to assign a passability score are clearly recorded and easily
auditable.
The method is based on the collection of flow depth and velocity measurements at different
points along an obstacle and some simple measurements to describe obstacle geometry.
Additional features of relevance to fish passage, such as a pool out of which a fish can leap, or
the presence of climbing substrate for eels, are also recorded. Flow depths and velocities are
then compared to published values on the swimming abilities of different fish species in order
to assign a passability score for each measurement point. Passability scores are also assigned
for the presence or absence of additional features. All passability scores are then combined to
come up with one overall estimate of passability for each species in both the upstream and
downstream directions.
Keywords: Water Framework Directive; Swimming performance; Flow depth;
Flow velocity
72
TARGETED MAINTENANCE, MILL OPERATING PROTOCOLS
AND RIVER RESTORATION STRATEGY
TO DELIVER FLOOD RISK MANAGEMENT AND
GOOD ECOLOGICAL POTENTIAL AT LEAST COST
R. A. CHASE1, & A. C. PAOLI
2
1Principal River Consultant – Atkins, Epsom, Surrey KT18 5BW [email protected]
2Civil Engineer – Atkins, Epsom, Surrey KT18 5BW
Abstract
The River Wensum is a chalk river and one of 31 whole river SSSIs in England and Wales,
and is currently in unfavourable condition. It is also one of 16 English rivers designated as a
Special Area of Conservation (SAC). Atkins has been commissioned by the Environment
Agency (EA) to produce 9 Feasibility and Environmental Scoping Reports to implement the
River Wensum Restoration Strategy over its entire 71 km length. 14 mills, owned privately
or by the EA, impound up to two-thirds of the Wensum‟s length. An extensive network of
Internal Drainage Board (IDB) drains discharge into the river, and the EA receives a precept
for maintenance. 4 villages are also at risk of flooding within the main river floodplain.
The Feasibility Reports provide outline restoration designs to address two of the primary
reasons for unfavourable conditions: siltation and physical modification. They also identify
options for better river management which sustains natural and improved ecological status
recovery through Targeted Maintenance Protocols (TaMPs). Historic physical modification is
addressed through the parallel development of Mill Operating Protocols (MOPs).
TaMPs aim to focus maintenance on the areas of direct need and avoid those where there are
no assets or flood risk, allowing the river to recover using natural processes. This approach
allows effective and efficient use of resources and ensures environmentally sensitive areas are
fully considered. Targeted areas include IDB channel confluences, bridges, built-up areas and
control structures. MOPs address the impoundments on the river whilst recognising their
benefits in terms of limiting the progression of silt downstream – these historic modifications
are therefore being used to allow recovery by natural processes. For the first time, through
agreement with all stakeholders, MOPs will allow consistent management for all drought and
flood flows whilst meeting requirements of the EA and private operators and owners.
The MOP and TaMP provide consistent action by each EA function and external stakeholders
and underpin the river restoration proposals for each SSSI unit. They focus the EA‟s limited
resources to ensure the most effective actions are taken to improve the condition assessment
of the SSSI, the SAC and Good Ecological Potential. The TaMP also directly satisfies EA
action in the Anglian River Basin Management Plan regarding the development of best
practice documents for river maintenance works to meet best or optimum ecological quality.
Keywords: Favourable condition; Siltation; Physical modification; Natural
processes; Good ecological quality; Best practice
73
DELIVERING A SUSTAINABLE APPROACH TO
CONTROLLING INVASIVE NON-NATIVE SPECIES
ON DUMFRIES AND GALLOWAY'S RIVERS
ANNE CONNICK
Catchment Management Planning Officer – SEPA, Newton Stewart [email protected]
Abstract
Invasive non-native species (INNS) are considered to be the 'greatest threat to biodiversity,
after habitat loss and destruction'. (*Convention on Biological Diversity').
The Dumfries and Galloway (D&G) INNS Project was started in 2007, on the rivers Nith and
Annan, in response to stakeholder concerns over the existing and emerging threats to our
rivers from INNS. It has come about through SEPA's D&G Catchment Management Initiative
(CMI) and Catchment Management Plans for the Nith, Annan and Dee-Ken, which have
highlighted INNS as a significant 'catchment management issue', as well as being listed in the
Solway-Tweed River Basin Management Plan (RBMP) as a 'significant water management
issue', with many waterbodies listed as adversely affected.
The project is co-ordinated by SEPA's CMI project officer, who is working with key river
stakeholders and landowners across the region, with practical work being managed by the
District Salmon Fishery Boards (DSFBs). The project dovetails with INNS project work
being undertaken across Galloway rivers by Galloway Fisheries Trust, and aims to provide
regional contact and support for education and practical control purposes for the INNS issue.
Key established species such as Japanese Knotweed and American Signal Crayfish have been
targeted so far, but the general INNS issue is also highlighted. The D&G projects are working
together to identify a long-term catchment scale, strategic approach to manage existing and
emerging INNS, meeting objectives of both the Solway-Tweed RBMP and the INNS
Framework Strategy for Great Britain.
Mapping has been undertaken since 2007, across the Nith and Annan catchments (and in
Galloway) to identify existing INNS, and two project officers were employed this year
through the DSFBs to start practical control work for some of the key species identified. A
website has been created (www.dgerc.org.uk/?q=inns), alongside an information leaflet on
key invasive river plants, which includes a reporting slip for the public to send sightings to a
central database. The project also aims to raise awareness with land managers away from the
riverside to encourage a universal preventative approach to INNS across the region. For the
duration of the project, staff will be working to reduce the extent of existing INNS to a level
where river managers are able to continue work in the future, and are experienced and
suitably trained to keep on top of the problem after funding has ended.
Keywords: Nith DSFB; Annan DSFB; SEPA Catchment Management Initiative;
Solway Heritage
74
NOTES…
75
FACILITATING THE APPLICATION OF OUTPUT FROM RESEARCH
AND CASE STUDIES ON ECOLOGICAL RESPONSES TO HYDRO-
MORPHOLOGICAL DEGRADATION AND REHABILITATION
(FORECASTER)
I. COWX1, T. BUIJSE
2 & N. ANGELOPOULOS
3
1Professor of Applied Fisheries Science – University of Hull, East Yorkshire HU6 7RX
[email protected] 2Senior Researcher/Advisor (Ecology) – Deltares, Utrecht, Netherlands
3Research Assistant – Hull International Fisheries Institute, University of Hull, East Yorkshire
Abstract
FORECASTER is a European project that has been selected for funding from the 1st call of
the IWRM-NET. It is funded by various national organisations across Europe. The project
aims at linking river restoration science with practice to support the implementation of robust,
cost-efficient rehabilitation strategies for improving rivers and floodplains. The main
objective of the project is to assess research outputs and case studies concerning the
ecological effects of hydro-morphological degradation and positioning hydromorphology in
river rehabilitation strategies. The focus is on the effectiveness to enhance hydrology,
morphology and aquatic ecology (fish, aquatic flora, benthic invertebrates).
To give end-user access to the information, FORECASTER has developed a web-based
geowiki tool (http://forecaster.deltares.nl). This tool is a knowledge and information system
relating hydromorphology and ecology of European rivers. The system presents a compilation
of case studies describing the output from river restoration projects as well as knowledge on
the impact of pressures and the effectiveness of restoration and mitigation measures. It is
intended to help practitioners by presenting experiences about success or failure of the
application of different measures. The tool is based on a combination of Google Maps and
the WIKIPEDIA approach. Thus users can consult the tool either geographically or by theme.
Moreover they can become a contributor. As a contributor, people can enter new case studies
on river restoration or improve existing information in the webtool.
Keywords: Geowiki webtool; Hydromorphology; Rehabilitation strategies;
River-floodplain ecosystem; River restoration
76
IMPLEMENTING A MONSTER
RIVER RESTORATION PROGRAMME
JO CULLIS1, BEN BAILEY
2 & DIANNE MATTHEWS
3
1Principal Environmental Consultant – Halcrow Group Ltd., Burderop Park, Swindon, Wiltshire, SN4 0QD
[email protected] 2Water Level Management Plan Officer – Environment Agency, Blandford Forum, Dorset, DT11 8ST
3Lead River Avon Advisor – Natural England, South Wiltshire, South West Region
Abstract
A strategic restoration plan for the River Avon (November 2009) assessed the physical
functioning of the river, and how it impacts on river ecology. The Plan sets out actions to
restore the river to a better condition for characteristic fauna and flora. The key goal is to
move towards a more naturally functioning and un-constrained system that can adjust and
respond to changes without constant management.
Implementing the whole of the Plan would mean a programme of river restoration for 203
reaches representing a total length of 213 km. The total estimated cost for this work is just
under £31m. This is clearly a massive programme of works, especially given the current and
likely future economic climate. To ensure that a realistic programme could be progressed, we
needed to find a way of turning this monster into something more manageable. To this end,
we developed an approach to prioritising the reaches and verifying the options, to produce a
primary costed programme, whilst achieving as much ecological benefit as possible.
The result of this work is a prioritised programme of river restoration for 55 reaches with a
total length of 60km, as agreed with Natural England. These reaches represent the top 28% of
the prioritised reaches where implementing river restoration projects will have the greatest
impact, in terms of ecological connectivity, addressing key impounding structures and
assisting natural recovery. This programme also primarily addresses works of an engineering
scale and complexity that would be unfeasible to be undertaken by volunteers or local groups.
It is expected that progressing these prioritised sites will provide the catalyst for river
restoration works on the other lower priority reaches. One of the first steps will involve
verifying the options of the lower-priority reaches, so that all work that can be done by others
(such as fishing clubs, local community groups etc.) is co-ordinated and undertaken in a
logical manner.
The delivery of strategic river restoration on the River Avon (the 203 river reaches identified
by the Plan) will not be achievable without a comprehensive and effective partnership
programme including the key stakeholders and led by the Environment Agency over a long
time frame. The project aims to successfully meet government targets under PSA3 and the
Water Framework Directive, and to maximise opportunities to contribute to Outcome
Measure 4, and potentially the creation of BAP habitat for OM5. To achieve this, the delivery
of the initial programme (the 55 highest priority reaches) by the Environment Agency
working in partnership with others is vital.
This paper summarises the essential steps we have taken in turning this river restoration
monster into something more manageable and realistic.
Keywords: River Avon; Strategic; Prioritisation; Partnership; Restoration Plan
77
BUILDING IN SUSTAINABILITY –
THE USE OF SYNTHETIC GEO-TEXTILES IN RIVER RESTORATION
P. F. EASTON1 & S. CAIN
2
1Senior Consultant – Cain Bio-Engineering Ltd, Lower Woodford, Salisbury, Wiltshire, SP4 6NQ
[email protected] 2Managing Director – Cain Bio-Engineering Ltd
Abstract
The Challenge:
The task of restoring dredged river channels presents numerous challenges. Typically the river
bed, banks and plan form will have been substantially compromised with an outcome
characterised by over-wide, steep sided channels, sub-optimal laminar flows and a uniform
substrate.
The Solution:
Restoration plans generally involve restoring sinuosity, a more appropriate and varied channel
width, diverse flow patterns and a variety of river bed profiles with transitional emergent
marginal habitats.
In most cases dredged arisings will have been deposited on the immediate bank edge to form
a graded flood bank that isolates the river from its flood plain. These dredgings provide an
ideal and easily accessible material for use in river bank construction. However forming them
into robust erosion-proof structures presents challenges.
Over the past 5 years Cain Bio-engineering has successfully field-trialed techniques that
combine natural and synthetic materials to form durable low-level flood berms. These
structures maximise the use of reclaimed dredged materials and natural gravels thereby
minimizing the need for imported materials.
Using these techniques we have been able to install erosion-resistant structures that provide a
durable framework into which traditional soft engineering techniques such as LWD & CWD
can be integrated. The finished structures provide a natural looking and complimentary
environmental outcome and have been successfully used in SSSI‟s and SAC‟s to create a
diverse range of riverine and marginal habitats.
Keywords: Bio-Engineering; Soft engineering techniques; Durability
78
PRACTICAL RIVER APPRAISAL GUIDANCE FOR MONITORING
OPTIONS (PRAGMO)
J. ENGLAND1, D. HAMMOND
2, J. MANT
3, J. HOLLOWAY
4 N. ELBOURNE
5 & M. JANES
6
1Environmental Monitoring Team Leader – Environment Agency, 2 Bishop Square Business Park, St.Albans
Road West, Hatfield, HERTS AL10 9EX [email protected] 2Senior Projects Adviser – The River Restoration Centre, Cranfield, Bedfordshire
3Science and Technical Manager – The River Restoration Centre
4Projects Adviser – The River Restoration Centre
5Information Officer – The River Restoration Centre
6Director – The River Restoration Centre
Abstract
With any river restoration and associated floodplain work there is a need to measure the
success or failure of the scheme to demonstrate its environmental benefit. In order to quantify
the degree of project success or failure some form of monitoring needs to be carried out.
Collated data can then help to increase the knowledge base and identify which techniques, or
suite of techniques, are most successful for a range of river types and project objectives. As a
result, both future project uncertainty and risk of failure can be reduced.
However, project monitoring is often omitted due to perceived financial constraints and a lack
of guidance. The process of designing a “fit for purpose” monitoring or project appraisal
method that can answer project objectives or questions is therefore often not given due
attention. Even when quantitative (e.g. fish counts) and/or qualitative data (e.g. repeat
photography) has been collected, demonstrating that the original objective has successfully
been achieved (e.g. improve salmonid fry habitat or increase hydro-morphological diversity)
is often difficult.
To help address some of these issues the River Restoration Centre has worked with other
organisations and specialists to collate and develop a set of pragmatic guidelines to help the
end user determine the most appropriate level of project monitoring for a given set of
measurable objectives based on the size, complexity and risk of the restoration project.
Thus the proposed monitoring protocol for large, complex catchment-scale projects may
differ from the small reach-scale schemes which are using already tried and proven restoration
techniques. It is anticipated that the document will be widely available during 2011 in a web
based format.
If you want to learn more about monitoring and river restoration schemes you may want to
consider the training workshops provided by the River Restoration Centre – please see the
website for details: www.therrc.co.uk
Keywords: River Restoration; Prioritisation; Assessment; Survey
79
METAL CONCENTRATIONS IN SEDIMENTS WITHIN
RESTORED AND UN-RESTORED LONDON RIVERS
H.M. GIBBS1, A.M. GURNELL
2, C.M. HEPPELL
3 & K.L. SPENCER
3
1PhD Student - School of Geography, Queen Mary, University of London, Mile End Road, London
E1 4NS [email protected] 2Professor of Physical Geography - School of Geography, Queen Mary, University of London
3Senior Lecturer - School of Geography, Queen Mary, University of London
Abstract
Sediments within rivers act as a store for various contaminants including metals. The extent
to which these sediments store metals, and therefore their quality, is dependent upon a number
of physiochemical sediment characteristics including grain size, redox potential and organic
matter content. As urban rivers are increasingly being restored through techniques such as
bed and bank protection removal, re-meandering and in-channel enhancement, the hydraulic
and physical conditions within the river channels are being altered. However, significant
consideration has not yet been given to understanding how these restoration practices impact
upon contaminant storage and hence ecosystem health in urban rivers.
This poster reports on an investigation of sediment quality, in terms of metal concentrations,
in different bed sediment types within restored and un-restored river reaches in London. Four
sites with adjacent restored and un-restored reaches were sampled at three times of the year,
May, August and November, to coincide with the beginning, middle and end of the in-channel
vegetation growing season. Surface sediment was sampled from unvegetated patches of
different bed sediment calibre (gravel, sand, silt & clay) and also from sediment surrounding
in-channel vegetation stands. The sediment was analysed for a range of metals (Ag, Al, Cd,
Cr, Cu, Fe, Mn, Ni, Pb and Zn) and sediment characteristics, including organic matter content
and grain size. The poster presents and discusses the spatial and temporal variations in metal
concentrations found in these sediments, noting contrasts: between the four sites; between
restored and un-restored river reaches; and, between different patch types, particularly
emphasising the impact of in-channel vegetation on metal retention. Published sediment
quality guidelines are used to evaluate the significance of the observations for river ecosystem
health and also for the design, management and use of restored urban rivers.
Keywords: Sediment quality; River restoration; Riverine sediment;
Heavy metals; In-channel vegetation.
80
NOTES…
81
UTILISING RIVER RESTORATION TO IMPROVE WATER QUALITY
D. M. HAMMOND1 & A. SCOTT
2
1Senior Projects Adviser – The River Restoration Centre, Cranfield Campus, Cranfield, Bedfordshire,
MK43 0AL [email protected] 2Lead Environmental Advisor – Yorkshire Water, Bradford BD6 2SZ
Abstract
The River Restoration Centre (RRC) carried out a scoping study on behalf of Yorkshire Water to
investigate the potential for using river restoration techniques to improve the water quality of receiving
waters in eight small sewage treatment work sites and one combined sewer outfall (CSO) site. All the
receiving watercourses have had a history of anthropogenic management/alteration and all but three
were in the coal mining region of Yorkshire with its associated landscape disturbance and pollution.
The type of management that the receiving waters had experienced included dredging, channel
widening, mine drainage discharge, impoundment by weirs, discharge of motorway drainage, channel
re-alignment, channel straightening, bank mowing, flow bifurcation and hard engineered revetments.
The outcome of the scoping study was to identify one or two potential cases which could be taken
through to a pilot study phase whereby river restoration will be carried out to determine whether there
is an improvement in water quality once the restoration has been carried out. At least one watercourse,
Cudworth Dike, has been identified as a potential for a pilot study. This poster briefly introduces
Cudworth Dike and explains the potential options for river restoration including channel narrowing,
recreation of flow sinuosity using deflectors and thinning of riparian trees along with the introduction
of more appropriate bank management techniques.
Keywords: Deflectors; Channel narrowing; Appropriate bank management
82
PREDICTING ECOLOGICAL GAINS
FOLLOWING ASSISTED NATURAL RECOVERY:
AN EXAMPLE FROM THE RIVER RIBBLE AT LONG PRESTON DEEPS
G. L. HERITAGE1 & K. SHEEHAN
2
1Technical Director – JBA Consulting, The Brew House, Wilderspool Park, Greenall's Avenue, Warrington
WA4 6HL [email protected] 2Senior Analyst – JBA Consulting, Denison House, Hexthorpe Road, Doncaster, South Yorkshire DN4 0BF
Abstract
Given the objective of the Water Framework Directive to improve the ecological integrity of
Europe‟s water bodies, there is a clear requirement to understand the linkages between the
geomorphology, hydrology and ecology and thereby establish a sustainable, process driven,
basis for river and floodplain restoration in the UK. An understanding of these linkages will
allow natural features to be restored through the re-establishment of natural morphological
processes and dynamics.
The river restoration plan for the River Ribble at Long Preston Deeps, North Yorkshire (a
SSSI), was developed through identifying the key geomorphological and ecological
associations, establishing the present day baseline state of the system through expert survey
and defining key restoration zones through simple 2D surface water flow modelling. The
results of this exercise permitted the prediction of the development of likely future habitats,
following the implementation of restoration measures designed to re-establish river-floodplain
process connectivity.
It was clear from the combined geomorphology-ecology survey that physical disruption to the
floodplain flow inundation regime, combined with inappropriate river and floodplain
management, were the primary drivers behind the degraded physical and ecological condition
of the SSSI. The associations between key species and river morphology were determined
from less impacted sites across the SSSI. This, combined with previously published
hydrological requirements for wetland communities, allowed for optimal flood regime
conditions, restoring floodplain processes to be established across the SSSI. This permitted
the effects of targeted palaeo-feature restoration to be modelled and facilitated the selection of
key locations thereby achieving optimum ecological improvements with minimal direct
intervention. The approach chosen will minimise disruption to the site and reduce costs,
whilst reinstating natural geomorphological, hydrological and ecological links and ensuring
the long term sustainability of each planned intervention.
Keywords: Hydromorphology; Geomorphology; Floodplain; SSSI;
River Restoration
83
THE HYDROMORPHOLOGICAL CONSEQUENCES
OF CHANNEL MANAGEMENT:
LESSONS FROM UPLAND SYSTEMS IN THE UK
G. L. HERITAGE1, N. S. ENTWISTLE
2 & D. MILAN
3
1Technical Director – JBA Consulting, The Brew House, Wilderspool Park, Warrington WA4 6HL
[email protected] 2Lecturer – Built and Human Environment Research Institute, Salford University, Manchester M5 4WT
3Senior Lecturer – Department of Natural & Social Sciences, University of Gloucester, Cheltenham GL50 4AZ
Abstract
The hydromorphic variation of the majority of UK rivers has been altered as a result of flow
modification, engineering works and land management. This paper reviews the present state
of upland floodplain dominated river systems in the UK, mapping hydromorphologic
complexity and comparing patterns across sites.
As would be anticipated the poorest general hydromorphology (as defined by the spatial and
temporal diversity and variability of hydromorphic units) is associated with heavily modified
systems, particularly where the channel-floodplain connectivity is degraded from natural. It
would appear that the most natural of UK upland floodplain rivers exist as alluvial
anastomosing systems, developing an intricate and closely linked network of sub-dominant
channels associated with a primary active channel. Sub-dominant channel activation is
frequently helping to generate flow and morphological diversity and stabilising the channel
network within the bounds of the anastomosing channel system.
In contrast, rivers where the floodplain has been significantly modified through vegetative
clearance and sub-channel infilling display a wandering character with poorer hydraulic
variability, extensive areas of relatively uniform and unstable gravels, severe local bank
instability and reduced temporal hydromorphic variability. This hydromorphic degradation is
observable on upland rivers where the flow regime has not been significantly altered
suggesting that land management is the primary cause behind the loss of hydraulic variability
and increased channel instability.
Based on these findings it is suggested that hydromorphic restoration of such systems is
primarily reliant on altering floodplain farming practices to allow anastomosing channels
through wet woodland to redevelop.
Keywords: Hydromorphology; Geomorphology; Floodplain; Anastomosed;
Upland rivers
84
AN ECOLOGICAL VISION FOR THE RIVER LUGG SSSI
B. LASCELLES1, MARK LANG
2 & KATHERINE BRADSHAW
3
1Technical Director – Hyder Consulting, The Mill, Brimscombe Port, Stroud, Goucestershire, GL5 3QG
[email protected] 2Principal Ecologist – Hyder Consulting, The Mill, Brimscombe Port, Stroud, Goucestershire, GL5 3QG
3Technical Director – Hyder Consulting, 9/10 St Andrew Square, Edinburgh, EH2 2AF
Abstract
The River Lugg, designated as a SSSI for its entire length and as an SAC in the lower reaches,
is considered to be one of the finest examples of both a clay river and a river displaying a
transition from nutrient-poor to naturally nutrient-rich water chemistry. However, the channel
has, in places, been physically modified (as a result of the presence of bridges and weirs, the
development of flood defences and channel straightening or canalisation), and it is generally
considered that these modifications are having an impact on the riverine ecology, limiting the
potential of this system.
A separate vision was produced for each of the River Types that the SSSI supported, pulling
together geomorphological assessment and analysis and ecological interpretation at a whole
river scale. The vision characterised the generic impacts of physical modifications and the
consequent benefits of restoration, and provides a broad vision for what restoration would
seek to achieve in terms of geomorphological form and function, habitat provision and visual
character. The River Lugg provides many examples of its natural form, providing habitat
suitable for its characteristic ecology and these sections were used to show what the benefits
of restoration on the whole river could be.
Photographic representation of the issues resulting from physical modifications, as well as
what the naturally functioning system should look like, were used extensively through the
vision. Gaps in existing data were highlighted and the key next steps to taking the vision
forward set out. It is intended that this ecological vision will provide a foundation for
subsequent detailed river geomorphological evaluation/interpretation and whole-river
restoration planning.
Keywords: River restoration; Biodiversity; Weir removal; Geomorphology;
Physical modifications
85
LOCAL PARTNERSHIP AND MECHANICAL EXCAVATORS DELIVER
VALUE FOR MONEY AND SUSTAINABLE RIVER RESTORATION
A. MAXWELL1, R SLOCOCK
2 & A FRAKE
3
1Water Level Management Plan Project Officer – Environment Agency, Rivers House, Sunrise Business Park,
Blandford, Dorset DT11 8ST [email protected] 2President – Frome, Piddle and West Dorset Fishery Association, Lawrences Farm, Southover, Tolpuddle
3Independent River Consultant – Timbergreen House, Sturminster Marshall, Wimborne
Abstract
Through the River Frome Water Level Management and Rehabilitation Plans, the Frome
SSSI is benefitting from a new approach to river restoration, through both partnership projects
and cost-effective and sustainable approaches to design and construction. Promoted locally as
best practice, so far, projects have been carried out at Woodsford and Moreton.
Moreton Channel was chosen partly due to the poor physical condition of the river but also
due to the willingness of the Frome, Piddle and West Dorset Fishery Association and the
fishing syndicate to work together with the Environment Agency (EA). This partnership
project was match funded between the EA and the Association. The scheme was designed by
EA staff and delivered through the Association. A long reach machine was used to diversify
the existing gravels of the channel bed profile. Large woody debris was introduced to the
channel through the hinging of riparian willow and alders. The hinging technique allows the
limbs to stay alive and so further growth within the channel is possible.
The partnership approach enabled good value for money, garnered a strong sense of
ownership by the Association and will be adopted on future projects through the catchment.
Woodsford Channel was a reach chosen as one of the most degraded on the River Frome
SSSI. Historically it had been dredged, removing significant amounts of the natural bed
material to reduce flood risk and improve drainage for intensive farming needs. There was a
lack of in-channel and bank profile diversity with little habitat to support the SSSI features.
The EA's internal workforce delivered this project using a similar approach to Moreton.
Existing gravels were moved within the channel creating deep pools, riffles and exposed
berms, diversifying available habitats and flow patterns. Banks were also reprofiled,
increasing the marginal zone and large woody debris was introduced.
The Woodsford project showed what could be achieved with one man and a machine,
compared to more traditional, labour-intensive projects. Zero waste was created and, apart
from the trees, no material was brought onto site. The project was also designed to be long-
lasting and self-sustaining. Both projects are considered highly successful by local river users
and will be used as a template for delivery within the River Frome Rehabilitation Plan.
Keywords: Large woody debris; Gravel; In-channel morphology;
Bank reprofiling; Flow diversity
86
NOTES…
87
DEVELOPING COST-EFFECTIVE RESTORATION OPTIONS
FOR THE NANT MILLS FISH PASS
J. A. MOON1, & R. JONES
2
1Senior Geomorphologist – Black & Veatch, Treenwood House, Rowden Lane, Bradford-on-Avon, Wiltshire,
BA15 2AU [email protected] 2Principal Engineer – Black & Veatch, Bradford-on-Avon, Wiltshire
Abstract
The Afon Gwyrfai rises near Rhyd Ddu in the north-west of Snowdonia National Park and
passes through a large lake, Llyn Cwellyn, on its way to the sea near Caernarfon. Dŵr Cymru
Welsh Water (DCWW) is currently licensed to abstract water at Llyn Cwellyn and Nant
Mills. The Gwyrfai is designated as a Special Area of Conservation (SAC) and one of the
qualifying features of this SAC is the presence of Atlantic salmon. An assessment undertaken
in 2009 concluded that historic structural modifications to the Nant Mills weir/fish pass had
rendered it impassable to fish during low flow conditions.
Following a Review of Consents, the Environment Agency recommended the removal of the
weir/fish pass because (1) it was considered the least cost solution in terms of capital outlay
and maintenance; (2) the abstraction was no longer utilised; and (3) removal would have a
positive effect on restoring the watercourse to its natural condition, helping to achieve Good
Ecological Potential status under the Water Framework Directive. Black & Veatch Ltd
(B&V) was retained by DCWW to investigate feasibility of removal of the weir/fish pass and
develop an outline design for a scheme to facilitate the migration of Atlantic salmon.
A geomorphological and hydraulic assessment was undertaken to consider the impacts of
scour erosion caused by the removal of the weir/fish pass. The key objectives were to review
the implications of removal on geomorphology and habitats within the SAC and in particular
to identify any erosion/depositional issues resulting from works within the channel, and also
to minimise the amount of future maintenance required. Erosion potential was determined by
utilising the stream power screening tool, along with developing an understanding of the
baseline geomorphology and historic channel dynamics.
The assessment identified that the unmitigated removal of the weir/fish pass was unlikely to
be an acceptable solution due to reduced water levels upstream and the potential for
substantial vertical incision of the channel bed. These combined effects would have exposed
an upstream bedrock ledge, creating a new, larger obstruction to fish passage.
B&V developed a solution comprising the replacement of the existing weir/fish pass with a
new „rock ramp‟. This represented the least cost solution to facilitate salmon migration, and
allowed the channel to revert to a more natural state.
Keywords: Restoration; Geomorphology; Stream power; Fisheries; Abstraction;
Rock-weir.
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MORPHOLOGICAL ADJUSTMENT AND ECOLOGICAL RESPONSE TO
TRIBUTARY RECONNECTION IN AN UPLAND RIVER
E. C. QUINLAN1, C. N. GIBBINS
2, R. J. BATALLA
3 & D. VERICAT
3
1PhD student – Northern Rivers Institute, University of Aberdeen, Aberdeen AB24 3UF
[email protected] 2Senior Lecturer – Northern Rivers Institute, University of Aberdeen, Aberdeen AB 24 3UF
3Senior Lecturers – Dept. of Envt. and Soil Sciences, University of Lleida, E-25198 Lleida, Catalonia, Spain
Abstract
The river Ehen, West Cumbria, designated as a Special Area of Conservation (SAC), is
regulated naturally by Ennerdale Water. Engineering works constructed in the 1970s raised
the level of the weir and allowed greater storage capacity in the lake and ensured a more
secure potable water supply. As part of these works, one of the tributaries of the Ehen was
diverted to Ennerdale Water, further supporting abstractions. As an important source of water
and sediment to the mainstem channel has been disconnected, there are concerns that the
tributary diversion may be compromising the ecological integrity of the river.
This poster describes work which aims to assess the effects of reconnecting the tributary to
the Ehen. Assessment of tributary sediment yield will be coupled with digital elevation and
hydraulic models of reaches in the Ehen downstream of the confluence, to assess the likely
hydrologic, sedimentologic and geomorphic responses to reconnection. Continuously
logging optodes installed within the stream bed at impact and reference sites will provide data
on dissolved oxygen levels within the hyporheic zone; data will be used to assess how the
suitability of conditions for invertebrates and salmonid eggs might be affected by the
predicted hydrological and sedimentological changes.
Keywords: Tributary reconnection; Digital elevation models, Hydraulic models;
Hyporheic zone
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SOME SIMPLE TOOLS FOR COMMUNICATING THE BIOPHYSICAL
CONDITION OF URBAN RIVERS TO SUPPORT HIGH-LEVEL
DISCUSSIONS REGARDING RIVER RESTORATION
LUCY SHUKER
PhD researcher – Queen Mary, University of London, Mile End Road, London E1 4NS [email protected]
Abstract
This poster illustrates a set of simple tools that may be used to assess the biophysical
condition of river and riparian habitat in urban catchments. The tools are based upon
information collected using the Urban River Survey (URS): a habitat survey designed for
application to 500m stretches of urban river corridor. The poster compares examples of how
these simple tools may be used to communicate information about urban river conditions at
both reach and catchment scale to a wide range of non-technical stakeholders and local
community members; to support high level discussions and decision-making relating to:
initial site selection for restoration; to post project appraisal; WFD objectives for HMWBs
and to contribute to the sustainable and integrated socio-environmental management of urban
blue ribbon and green grid networks.
Example applications are provided using data from URS surveys undertaken on tributaries of
the River Thames within London displaying a range of characteristics within both restored
and un-restored stretches of modified river channel. These tools are being used in London as
part of a broader interdisciplinary ESRC/NERC research project that is testing the suitability
of this type of approach in the context of the London Rivers Action Plan, Water Framework
Directive, urban blue space regeneration, place-making and climate change adaptation
principles.
Keywords: Urban river restoration, habitat assessment, blue green connectivity,
WFD, ecological potential, HMWB
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NOTES…
91
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SITE VISIT INFORMATION
(FRIDAY 15TH APRIL)
Croxall Lakes
A very large proportion, if not most, rivers in lowland England have been re-sectioned to a trapezoidal
profile with very steep banks with an angle of 1:3-4. This cross section can be self maintaining where
the channels were specifically designed to be “self-cleansing” i.e. not to allow deposition of gravel and
silt. These channels were based on keeping the narrowest existing river cross section and making the
whole river to that width. It has therefore become clear that the only way to create self sustaining in-
stream habitat is to widen channels in such places. This re-establishes a more natural variation in
channel width. This is most easily done on the inside of bends where it is possible to mimic a natural
tick shaped channel profile by pulling back the bank. It became clear that the key factor in this was to
increase the channel cross sectional area very considerably to allow slowing of flow, deposition of
gravels, resulting in raising of bed levels creating riffles and thus kick starting the process of self
restoration. This is of course in addition to the directly created habitats.
Earlier work at the site
Stage 1 (1997) Along 400m of the Tame an underwater shelf about 4m wide was excavated to just below water level
and the bank sloped back to an angle of 1:20 to a maximum of 30m at the point of the bend. The river
in this reach had a very even width of about 25m before the works.
Stage 2 (2002) It became clear that a larger increase in cross section at high flows would have been desirable. In
2002, the 400m of land between the river and the lake (an area of about 2.7ha) was lowered by
750mm. The highest point was lowered from 1.6 to about 0.85m above normal water level. The river
height at bank full level was thus similarly lowered thus reducing velocity and thus increasing
deposition on the bend. The soil was again put into the lake to create shallows.
Stage 3 (2008) There was a 300mm pipe linking the pool at Croxall to the river. This was put in when gravel working
on the site ceased. It allowed river water to enter and drain from the lake quite slowly, kept the lake
level generally higher than the river and did not allow fish to move between the lake and the river.
The poor in-channel habitat on the River Tame, combined with intermittent poor water quality events
have retarded the development of sustainable fish stocks. To counter that the EA has created a series
of “fish refuges/spawning areas” by linking pools to the river. In 2002 the pipe was replaced by a
lower level open channel about 6m wide at bank top. This allows fish to enter and leave the pool and
also lowered the lake level thus creating better shallows for waders.
Lessons Learnt It became clear that the restoration works could have been even bolder by lowering the whole of the
bend down to lake/river level. This experimental work on the Tame at Croxall gave confidence that
widening, combined with allowing river processes to work was an answer to the problems of poor
channel structure in gravel rivers. This confidence was part of the background to the much larger
scheme carried out by the Wildlife Trust on the Tame/Trent at Croxall.
93
Latest Phase of Works at Croxall The work was carried out by Nick Mott of Staffordshire Wildlife Trust in partnership with Lafarge
Aggregates, Landfill Communities Fund, Natural England, The National Forest Company, the
Environment Agency, Network Rail and May Gurney.
Aims The main aim was to recreate some of the habitats which were once common features along our main
rivers prior to their modification in the 19th
and 20th
centuries. The river has been heavily engineered
in the past and was once much shallower and wider. The project aims at allowing natural river
processes to occur by widening the channel (to over 90m in some places) encouraging it to become
active in terms of deposition and bed-scouring.
Table 1 Scheme Summary
Works Driver
540 metres of river re-habilitation (UK & LBAP Target for Rivers)
1.85 ha area of river widening (UK & LBAP targets for creation of new wetlands)
1.2 ha of shallows created for new reedbed planting
Approximately 40,000 cubic metres (80,000 tonnes) of soil was removed from the riparian zone and transported to the lake deposition areas.
Baseline surveys carried out for UK & LBAP (& other indicator) species
Baseline geomorphological survey carried out including a 1D Hydraulic model
The scheme cost £161,000 of which £144,000 was capital works.
Wildlife
Baselines survey information has been collated for a number of invertebrate, bird, amphibian, fish,
mammal and plant species at Croxall. UK and Staffordshire BAP wetland species recorded within two
kilometres and within the last ten years include: white-clawed crayfish, harvest mouse, otter, water vole,
common toad, eel, barn owl, snipe, lapwing, reed bunting and native black poplar.
The UK BAP species, depressed (or compressed) river mussel has been recorded within three kilometres
of the site. This is a species which is being targeted for specific survey work at Croxall to ascertain
whether the habitats created during the scheme prove suitable for colonisation.
Now the works have been completed Stafforshire Wildlife Trust will be carrying out repeat surveys
for BAP and other indicator species at the site. It should be noted that significant numbers of waders
were recorded during and shortly after completing- the scheme. Snipe, lapwing, green sandpiper,
common sandpiper and redshank were all frequent visitors to the new wetland area. Links with
universities are in place to ensure that ongoing research and monitoring is carried out.
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Figure 1 Croxall Lakes site map
Annotated aerial photo showing the scope of the works at Croxall Lakes. © The Environment Agency.
Figure 2 Aerial Photograph annotated with proposed works at Croxall Lakes
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Figure 3 Widened channel with bars and islands at the Tame – Trent confluence
Figure 4 Islands being created
Tuckers Holt Farm
The River Sence at Tuckers Holt Farm has been extensively straightened due to mineral extraction and
agricultural land gain. The land is owned by the Crown, but leased for farming and to Hansons
Aggregates for clay extraction. Fishing rights along the river are also let out separately. There are no
flooding issues, in terms of impacts on buildings or infrastructure.
Permission was gained from all the landowners and tenants and from the Environment Agency (Land
drainage consent), to introduce randomly placed large woody debris. The wood was sourced from the
Forestry Commission at Cannock and was placed in the channel to act as blockages/deflectors which
would encourage more scour and deposition of bed and banks (see Figure 5). This was supplemented
with 80 tonnes of river gravels to raise the river bed and create/ improve the habitat for white clawed
crayfish, brown trout and grayling that are found further downstream.
The project was mostly funded by the Environment Agency Fisheries, but was carried out by the Wild
Trout Trust. The £10k project was carried out in the spring of 2010 and will be further enhanced by a
new weir bypass channel (see weir in Figure 6) at the same site. The bypass channel will enable the
white clawed crayfish, trout and grayling to migrate upstream to other improving habitat which has
been enhanced by further introductions of large woody debris. This Environment Agency £13k
Biodiversity project is being carried out at the end of March 2011.
Figure 5 Large woody debris placed along river banks
Figure 6 Weir soon to be bypassed
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Sence Valley Forest Park
This area of Sence Valley Park formed part of a large opencast mining area covering around 460 acres.
Once coal extraction had finished in 1996, the soil was compacted and cultivated and a drainage
system was installed. Leicester County Council were given 150 acres to create a forest park, and the
park was opened as part of the National Forest in 1998 after being planted with more than 98,000
trees.
As part of the restoration work the River Sence, which had been diverted around the mine, was
reinstated to its original position. The Coal Board had planned to reinstate the river in a trapezoidal
channel, but the Environment Agency insisted on a more natural restoration.
The reinstated channel is largely constructed without bank reinforcement, although there are a few
small sections where stones have been used for support. This has been successful, and there have been
no major problems with erosion or collapse. The channel has naturally moved since its creation, with
areas of erosion and deposition and the formation of berms and meanders.
The new channel was dug quite deep for flood risk reasons, and it is subsequently felt that a shallower
channel with a higher bed level would be preferable. It is also recognised that fencing off the river
bank to create a buffer strip between the farmland and the river would help to improve the water
quality.
More recently further work has been carried out on the River Sence through Sence Valley Park.
Working with the Forestry Commission and Sence Valley Volunteer Group, the Environment Agency
have carried a project to enhance 600m of the artificial river channel that was formed 15 years ago as a
narrow incised channel after extensive opencast coal extraction.
The £20k project was funded out of the FCRM Biodiversity project pot and resulted in WFD
improvements through re-grading and widening of bends, adding large woody debris as flow
deflectors and habitat diversity, cutting 2 new meanders (see Figures 7 to 9), and removal of an
artificial rock chute weir that was impounding water and disrupting natural flows.
After discussions with Lafarge aggregates, they also agreed to be a partner in the project and supplied
100 tonnes of river gravels to help improve the bed structure, spawning quality and ecology of the
restored section. Spoil from the works was lost in the margins of the adjacent lake to create shallows
to enable BAP habitat (reedbed) creation by the volunteer group. A viewing platform has been created
so visitors to the park can view the new river section and associated wildlife. This project co-ordinates
well with those downstream at Tuckers Holt Farm and will allow brown trout and grayling to move
upstream to establish and spawn, and so expand their current range.
Figure 7 Pre-works
Figure 8 New meander being excavated
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Figure 9 New meander
Figure 10 Sence Valley Forest Park site map
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